Your search keyword '"Robert G. Kranz"' showing total 101 results

1. Structural Insights into Mechanisms Underlying Mitochondrial and Bacterial Cytochrome c Synthases

Author

Pema L. Childs, Ethan P. Lowder, Deanna L. Mendez, Shalon E. Babbitt, Amidala Martinie, Jonathan Q. Huynh, and Robert G. Kranz

Subjects

heme, cytochrome c, heme attachment, cytochrome c synthase, structure, mechanisms, Microbiology, QR1-502

Abstract

Mitochondrial holocytochrome c synthase (HCCS) is an essential protein in assembling cytochrome c (cyt c) of the electron transport system. HCCS binds heme and covalently attaches the two vinyls of heme to two cysteine thiols of the cyt c CXXCH motif. Human HCCS recognizes both cyt c and cytochrome c1 of complex III (cytochrome bc1). HCCS is mutated in some human diseases and it has been investigated recombinantly by mutational, biochemical, and reconstitution studies in the past decade. Here, we employ structural prediction programs (e.g., AlphaFold 3) on HCCS and its two substrates, heme and cytochrome c. The results, when combined with spectroscopic and functional analyses of HCCS and variants, provide insights into the structural basis for heme binding, apocyt c binding, covalent attachment, and release of the holocyt c product. Results from in vitro reconstitution of purified human HCCS using cyt c and cyt c1 peptides as acceptors are consistent with the structural modeling of substrate binding. Reconstitution of HCCS and cyt c1 provides an approach to studying cyt c1 assembly, which has been refractile to recombinant in vivo reconstitution (unlike HCCS and cyt c). We propose a structural basis for release of the holocyt c product from HCCS based on in vitro studies and on cryoEM structures of the bacterial cyt c synthase (CcsBA) active site. We analyze the kinetoplastid mitochondrial synthase (KCCS), and hypothesize a molecular evolutionary path from mitochondrial endosymbiosis to the current HCCS.

Published

2024

2. Structures of the CcmABCD heme release complex at multiple states

Author

Jiao Li, Wan Zheng, Ming Gu, Long Han, Yanmei Luo, Koukou Yu, Mengxin Sun, Yuliang Zong, Xiuxiu Ma, Bing Liu, Ethan P. Lowder, Deanna L. Mendez, Robert G. Kranz, Kai Zhang, and Jiapeng Zhu

Subjects

Science

Abstract

Bacterial ABC transporter complex CcmABCD, a part of cytochrome c maturation system, transfers heme from one binding partner (CcmC) to another (CcmE). Here authors describe high resolution cryo-EM structures of CcmABCD in multiple states and propose a hypothetic model of heme trafficking, heme transfer and release of holoCcmE.

Published

2022

3. Photoferrotrophs Produce a PioAB Electron Conduit for Extracellular Electron Uptake

Author

Dinesh Gupta, Molly C. Sutherland, Karthikeyan Rengasamy, J. Mark Meacham, Robert G. Kranz, and Arpita Bose

Subjects

photoferrotrophy, phototrophic EEU, Rhodopseudomonas palustris TIE-1, decaheme cytochrome c, Fe(II)-oxidation, Microbiology, QR1-502

Abstract

ABSTRACT Photoferrotrophy is a form of anoxygenic photosynthesis whereby bacteria utilize soluble or insoluble forms of ferrous iron as an electron donor to fix carbon dioxide using light energy. They can also use poised electrodes as their electron donor via phototrophic extracellular electron uptake (phototrophic EEU). The electron uptake mechanisms underlying these processes are not well understood. Using Rhodopseudomonas palustris TIE-1 as a model, we show that a single periplasmic decaheme cytochrome c, PioA, and an outer membrane porin, PioB, form a complex allowing extracellular electron uptake across the outer membrane from both soluble iron and poised electrodes. We observe that PioA undergoes postsecretory proteolysis of its N terminus to produce a shorter heme-attached PioA (holo-PioAC, where PioAC represents the C terminus of PioA), which can exist both freely in the periplasm and in a complex with PioB. The extended N-terminal peptide controls heme attachment, and its processing is required to produce wild-type levels of holo-PioAC and holo-PioACB complex. It is also conserved in PioA homologs from other phototrophs. The presence of PioAB in these organisms correlate with their ability to perform photoferrotrophy and phototrophic EEU. IMPORTANCE Some anoxygenic phototrophs use soluble iron, insoluble iron minerals (such as rust), or their proxies (poised electrodes) as electron donors for photosynthesis. However, the underlying electron uptake mechanisms are not well established. Here, we show that these phototrophs use a protein complex made of an outer membrane porin and a periplasmic decaheme cytochrome (electron transfer protein) to harvest electrons from both soluble iron and poised electrodes. This complex has two unique characteristics: (i) it lacks an extracellular cytochrome c, and (ii) the periplasmic decaheme cytochrome c undergoes proteolytic cleavage to produce a functional electron transfer protein. These characteristics are conserved in phototrophs harboring homologous proteins.

Published

2019

4. Structure-Function Analysis of the Bifunctional CcsBA Heme Exporter and Cytochrome c Synthetase

Author

Molly C. Sutherland, Nathan L. Tran, Dustin E. Tillman, Joshua M. Jarodsky, Jason Yuan, and Robert G. Kranz

Subjects

CcsBA, ResBC, cytochrome c, cytochrome c biogenesis, heme, heme trafficking, Microbiology, QR1-502

Abstract

ABSTRACT Although intracellular heme trafficking must occur for heme protein assembly, only a few heme transporters have been unequivocally discovered and nothing is known about their structure or mechanisms. Cytochrome c biogenesis in prokaryotes requires the transport of heme from inside to outside for stereospecific attachment to cytochrome c via two thioether bonds (at CXXCH). The CcsBA integral membrane protein was shown to transport and attach heme (and thus is a cytochrome c synthetase), but the structure and mechanisms underlying these two activities are poorly understood. We employed a new cysteine/heme crosslinking tool that traps endogenous heme in heme binding sites. We combined these data with a comprehensive imidazole correction approach (for heme ligand interrogation) to map heme binding sites. Results illuminate the process of heme transfer through the membrane to an external binding site (called the WWD domain). Using meta-genomic data (GREMLIN) and Rosetta modeling programs, a structural model of the transmembrane (TM) regions in CcsBA were determined. The heme mapping data were then incorporated to model the TM heme binding site (with TM-His1 and TM-His2 as ligands) and the external heme binding WWD domain (with P-His1 and P-His2 as ligands). Other periplasmic structure/function studies facilitated modeling of the full CcsBA protein as a framework for understanding the mechanisms. Mechanisms are proposed for heme transport from TM-His to WWD/P-His and subsequent stereospecific attachment of heme. A ligand exchange of the P-His1 for histidine of CXXCH at the synthetase active site is suggested. IMPORTANCE The movement or trafficking of heme is critical for cellular functions (e.g., oxygen transport and energy production); however, intracellular heme is tightly regulated due to its inherent cytotoxicity. These factors, combined with the transient nature of transport, have resulted in a lack of direct knowledge on the mechanisms of heme binding and trafficking. Here, we used the cytochrome c biogenesis system II pathway as a model to study heme trafficking. System II is composed of two integral membrane proteins (CcsBA) which function to transport heme across the membrane and stereospecifically position it for covalent attachment to apocytochrome c. We mapped two heme binding domains in CcsBA and suggest a path for heme trafficking. These data, in combination with metagenomic coevolution data, are used to determine a structural model of CcsBA, leading to increased understanding of the mechanisms for heme transport and the cytochrome c synthetase function of CcsBA.

Published

2018

5. Cryo-EM of CcsBA reveals the basis for cytochrome c biogenesis and heme transport

Author

Deanna L. Mendez, Ethan P. Lowder, Dustin E. Tillman, Molly C. Sutherland, Andrea L. Collier, Michael J. Rau, James A. J. Fitzpatrick, and Robert G. Kranz

Subjects

Protein Transport, Cryoelectron Microscopy, Cytochromes c, Cell Biology, Heme, Molecular Biology

Abstract

Although the individual structures and respiratory functions of cytochromes are well studied, the structural basis for their assembly, including transport of heme for attachment, are unknown. We describe cryo-electron microscopy (cryo-EM) structures of CcsBA, a bifunctional heme transporter and cytochrome c (cyt c) synthase. Models built from the cryo-EM densities show that CcsBA is trapped with heme in two conformations, herein termed the closed and open states. The closed state has heme located solely at a transmembrane (TM) site, with a large periplasmic domain oriented such that access of heme to the cytochrome acceptor is denied. The open conformation contains two heme moieties, one in the TM-heme site and another in an external site (P-heme site). The presence of heme in the periplasmic site at the base of a chamber induces a large conformational shift that exposes the heme for reaction with apocytochrome c (apocyt c). Consistent with these structures, in vivo and in vitro cyt c synthase studies suggest a mechanism for transfer of the periplasmic heme to cytochrome.

Published

2021

6. In vitro reconstitution reveals major differences between human and bacterial cytochrome c synthases

Author

Dustin E Tillman, Noah T Prizant, Olga Melnikov, Robert G. Kranz, Molly C. Sutherland, Deanna L. Mendez, Shalon E. Babbitt, Nathan L. Tran, and Andrea L Collier

Subjects

Cytochrome, QH301-705.5, Science, Chemical biology, Lyases, Heme, In Vitro Techniques, General Biochemistry, Genetics and Molecular Biology, Substrate Specificity, chemistry.chemical_compound, Biochemistry and Chemical Biology, Catalytic Domain, synthases, Escherichia coli, Humans, cytochrome c biogenesis, Biology (General), chemistry.chemical_classification, Bacteria, General Immunology and Microbiology, ATP synthase, biology, heme attachment, General Neuroscience, Cytochrome c, Cytochromes c, General Medicine, biology.organism_classification, post translational modification, In vitro, Mitochondria, cytochrome c, Enzyme, Biochemistry, chemistry, biology.protein, Medicine, Other, Peptides, Research Article

Abstract

Cytochromes c are ubiquitous heme proteins in mitochondria and bacteria, all possessing a CXXCH (CysXxxXxxCysHis) motif with covalently attached heme. We describe the first in vitro reconstitution of cytochrome c biogenesis using purified mitochondrial (HCCS) and bacterial (CcsBA) cytochrome c synthases. We employ apocytochrome c and peptide analogs containing CXXCH as substrates, examining recognition determinants, thioether attachment, and subsequent release and folding of cytochrome c. Peptide analogs reveal very different recognition requirements between HCCS and CcsBA. For HCCS, a minimal 16-mer peptide is required, comprised of CXXCH and adjacent alpha helix 1, yet neither thiol is critical for recognition. For bacterial CcsBA, both thiols and histidine are required, but not alpha helix 1. Heme attached peptide analogs are not released from the HCCS active site; thus, folding is important in the release mechanism. Peptide analogs behave as inhibitors of cytochrome c biogenesis, paving the way for targeted control., eLife digest From tiny bacteria to the tallest trees, most life on Earth carries a protein called cytochrome c, which helps to create the energy that powers up cells. Cytochrome c does so thanks to its heme, a molecule that enables the chemical reactions required for the energy-creating process. Despite both relying on cytochrome c, animals and bacteria differ in the enzyme they use to attach the heme to the cytochrome. Spotting variations in how this ‘cytochrome c synthase’ works would help to find compounds that deactivate the enzyme in bacteria, but not in humans. However, studying cytochrome c synthase in living cells is challenging. To bypass this issue, Sutherland, Mendez, Babbitt et al. successfully reconstituted cytochrome c synthases from humans and bacteria in test tubes. This allowed them to examine in detail which structures the enzymes recognize to spot where to attach the heme onto their target. The experiments revealed that human and bacterial synthases actually rely on different parts of the cytochrome c to orient themselves. Different short compounds could also block either the human or bacterial enzyme. Variations between human and bacterial cytochrome c synthase could lead to new antibiotics which deactivate the cytochrome and kill bacteria while sparing patients. The next step is to identify molecules that specifically interfere with cytochrome c synthase in bacteria, and could be tested in clinical trials.

Published

2021

7. Author response: In vitro reconstitution reveals major differences between human and bacterial cytochrome c synthases

Author

Deanna L. Mendez, Olga Melnikov, Nathan L. Tran, Robert G. Kranz, Shalon E. Babbitt, Andrea L Collier, Molly C. Sutherland, Dustin E Tillman, and Noah T Prizant

Subjects

biology, Biochemistry, Chemistry, Cytochrome c, biology.protein, In vitro

Published

2021

8. Structurally Mapping Endogenous Heme in the CcmCDE Membrane Complex for Cytochrome c Biogenesis

Author

David Baker, Molly C. Sutherland, Sergey Ovchinnikov, Robert G. Kranz, and Joshua M. Jarodsky

Subjects

Hemeproteins, Models, Molecular, 0301 basic medicine, Heme binding, Stereochemistry, Heme, macromolecular substances, Article, 03 medical and health sciences, chemistry.chemical_compound, Bacterial Proteins, Structural Biology, Escherichia coli, Cysteine, Molecular Biology, Integral membrane protein, Binding Sites, 030102 biochemistry & molecular biology, biology, Chemistry, Escherichia coli Proteins, Cytochrome c, technology, industry, and agriculture, Cytochromes c, Membrane Proteins, Transporter, Protein Transport, 030104 developmental biology, Multiprotein Complexes, Chaperone (protein), Mutation, biology.protein, Biogenesis, Bacterial Outer Membrane Proteins, Protein Binding

Abstract

Although many putative heme transporters have been discovered, it has been challenging to prove that these proteins are directly involved with heme trafficking in vivo and to identify their heme binding domains. The prokaryotic pathways for cytochrome c biogenesis, Systems I and II, transport heme from inside the cell to outside for stereochemical attachment to cytochrome c, making them excellent models to study heme trafficking. System I is composed of eight integral membrane proteins (CcmA-H) and is proposed to transport heme via CcmC to an external "WWD" domain for presentation to the membrane-tethered heme chaperone, CcmE. Herein, we develop a new cysteine/heme crosslinking approach to trap and map endogenous heme in CcmC (WWD domain) and CcmE (defining "2-vinyl" and "4-vinyl" pockets for heme). Crosslinking occurs when either of the two vinyl groups of heme localize near a thiol of an engineered cysteine residue. Double crosslinking, whereby both vinyls crosslink to two engineered cysteines, facilitated a more detailed structural mapping of the heme binding sites, including stereospecificity. Using heme crosslinking results, heme ligand identification, and genomic coevolution data, we model the structure of the CcmCDE complex, including the WWD heme binding domain. We conclude that CcmC trafficks heme via its WWD domain and propose the structural basis for stereochemical attachment of heme.

Published

2018

9. Oxidized or Reduced Cytochrome c and Axial Ligand Variants All Form the Apoptosome in Vitro

Author

Christopher W. Akey, Deanna L. Mendez, Robert G. Kranz, and Ildikó V. Akey

Subjects

0301 basic medicine, In Vitro Techniques, Ligands, environment and public health, Biochemistry, Article, 03 medical and health sciences, chemistry.chemical_compound, Apoptosomes, Humans, APAF1, Inner mitochondrial membrane, Heme, 030102 biochemistry & molecular biology, biology, Ligand, Cytochrome c, Cytochromes c, enzymes and coenzymes (carbohydrates), Cytosol, 030104 developmental biology, chemistry, Apoptosis, embryonic structures, cardiovascular system, biology.protein, Biophysics, Apoptosome, Oxidation-Reduction

Abstract

Cytochrome c (cyt c) has two important roles in vertebrates: mitochondrial electron transport and activating the intrinsic cell death pathway (apoptosis). To initiate cell death, cyt c dissociates from the inner mitochondrial membrane and migrates to the cytosol. In the cytosol, cyt c interacts stoichiometrically with Apaf-1, and upon ATP binding induces formation of the heptameric apoptosome. It is not clear however what the redox state of cyt c is when it functions as the “active signal” for apoptosis. Some reports have indicated that only ferri (ie. oxidized Fe3+ heme) but not ferro (reduced, Fe2+ heme) cyt c forms the apoptosome. Facilitated by our recently described recombinant system to synthesize novel human cyt c proteins, we use a panel of cyt c axial ligand variants that exhibit a broad range of redox potentials. These variants exist in different redox states. Here we show that cyt c WT and cyt c H1-M (reduced state) and cyt c M81A and cyt c M81H (oxidized state) all bind to Apaf-1 and form the apoptosome.

Published

2017

10. Photoferrotrophs Produce a PioAB Electron Conduit for Extracellular Electron Uptake

Author

Robert G. Kranz, Dinesh Gupta, J. Mark Meacham, Molly C. Sutherland, Arpita Bose, and Karthikeyan Rengasamy

Subjects

Cytochrome, Iron, decaheme cytochrome c, Porins, Electrons, Microbiology, Electron Transport, 03 medical and health sciences, Electron transfer, Bacterial Proteins, Virology, Photosynthesis, Electrodes, 030304 developmental biology, 0303 health sciences, biology, Phototroph, 030306 microbiology, Chemistry, Applied and Environmental Science, photoferrotrophy, Cytochrome c, Cytochromes c, Biological Transport, Periplasmic space, Carbon Dioxide, biology.organism_classification, Anoxygenic photosynthesis, QR1-502, Rhodopseudomonas, Fe(II)-oxidation, Periplasm, Biophysics, biology.protein, phototrophic EEU, Rhodopseudomonas palustris TIE-1, Rhodopseudomonas palustris, Bacterial outer membrane, Research Article

Abstract

Some anoxygenic phototrophs use soluble iron, insoluble iron minerals (such as rust), or their proxies (poised electrodes) as electron donors for photosynthesis. However, the underlying electron uptake mechanisms are not well established. Here, we show that these phototrophs use a protein complex made of an outer membrane porin and a periplasmic decaheme cytochrome (electron transfer protein) to harvest electrons from both soluble iron and poised electrodes. This complex has two unique characteristics: (i) it lacks an extracellular cytochrome c, and (ii) the periplasmic decaheme cytochrome c undergoes proteolytic cleavage to produce a functional electron transfer protein. These characteristics are conserved in phototrophs harboring homologous proteins., Photoferrotrophy is a form of anoxygenic photosynthesis whereby bacteria utilize soluble or insoluble forms of ferrous iron as an electron donor to fix carbon dioxide using light energy. They can also use poised electrodes as their electron donor via phototrophic extracellular electron uptake (phototrophic EEU). The electron uptake mechanisms underlying these processes are not well understood. Using Rhodopseudomonas palustris TIE-1 as a model, we show that a single periplasmic decaheme cytochrome c, PioA, and an outer membrane porin, PioB, form a complex allowing extracellular electron uptake across the outer membrane from both soluble iron and poised electrodes. We observe that PioA undergoes postsecretory proteolysis of its N terminus to produce a shorter heme-attached PioA (holo-PioAC, where PioAC represents the C terminus of PioA), which can exist both freely in the periplasm and in a complex with PioB. The extended N-terminal peptide controls heme attachment, and its processing is required to produce wild-type levels of holo-PioAC and holo-PioACB complex. It is also conserved in PioA homologs from other phototrophs. The presence of PioAB in these organisms correlate with their ability to perform photoferrotrophy and phototrophic EEU.

Published

2019

11. Molecular Basis Behind Inability of Mitochondrial Holocytochrome c Synthase to Mature Bacterial Cytochromes

Author

Shalon E. Babbitt, Robert G. Kranz, and Jennifer Hsu

Subjects

0301 basic medicine, Cytochrome, biology, Cytochrome c, Cell Biology, HCCS, environment and public health, Biochemistry, digestive system diseases, Serine, enzymes and coenzymes (carbohydrates), 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Protein structure, chemistry, embryonic structures, cardiovascular system, biology.protein, Molecular Biology, Heme, Histidine, Cysteine

Abstract

Mitochondrial holocytochrome c synthase (HCCS) is required for cytochrome c (cyt c) maturation and therefore respiration. HCCS efficiently attaches heme via two thioethers to CXXCH of mitochondrial but not bacterial cyt c even though they are functionally conserved. This inability is due to residues in the bacterial cyt c N terminus, but the molecular basis is unknown. Human cyts c with deletions of single residues in α helix-1, which mimic bacterial cyt c, are poorly matured by human HCCS. Focusing on ΔM13 cyt c, we co-purified this variant with HCCS, demonstrating that HCCS recognizes the bacterial-like cytochrome. Although an HCCS-WT cyt c complex contains two covalent links, HCCS-ΔM13 cyt c contains only one thioether attachment. Using multiple approaches, we show that the single attachment is to the second thiol of C15SQC18H, indicating that α helix-1 is required for positioning the first cysteine for covalent attachment, whereas the histidine of CXXCH positions the second cysteine. Modeling of the N-terminal structure suggested that the serine residue (of CSQCH) would be anchored where the first cysteine should be in ΔM13 cyt c. An engineered cyt c with a CQCH motif in the ΔM13 background is matured at higher levels (2–3-fold), providing further evidence for α helix-1 positioning the first cysteine. Bacterial cyt c biogenesis pathways (Systems I and II) appear to recognize simply the CXXCH motif, not requiring α helix-1. Results here explain mechanistically how HCCS (System III) requires an extended region adjacent to CXXCH for maturation.

Published

2016

12. Heme Trafficking and Modifications during System I Cytochrome c Biogenesis: Insights from Heme Redox Potentials of Ccm Proteins

Author

Robert G. Kranz, Joel A. Rankin, and Molly C. Sutherland

Subjects

0301 basic medicine, Stereochemistry, Immunoblotting, Lyases, Heme, Biochemistry, Article, 03 medical and health sciences, chemistry.chemical_compound, Thioether, Escherichia coli, Integral membrane protein, 030102 biochemistry & molecular biology, biology, Cytochrome c, Cytochromes c, Membrane Proteins, Transport protein, Protein Transport, 030104 developmental biology, chemistry, Membrane protein, Covalent bond, biology.protein, Oxidation-Reduction, Biogenesis, Molecular Chaperones

Abstract

Cytochromes c require covalent attachment of heme via two thioether bonds at conserved CXXCH motifs, a process accomplished in prokaryotes by eight integral membrane proteins (CcmABCDEFGH), termed System I. Heme is trafficked from inside the cell to outside (via CcmABCD) and chaperoned (holoCcmE) to the cytochrome c synthetase (CcmF/H). Purification of key System I pathway intermediates allowed the determination of heme redox potentials. The data support a model whereby heme is oxidized to form holoCcmE and subsequently reduced by CcmF/H for thioether formation, with Fe(2+) being required for attachment to CXXCH. Results provide insight into mechanisms for the oxidation and reduction of heme in vivo.

Published

2016

13. Biosynthesis of single thioether c-type cytochromes provide insight into mechanisms intrinsic to holocytochrome c synthase (HCCS)

Author

Jennifer Hsu, Robert G. Kranz, Shalon E. Babbitt, and Deanna L. Mendez

Subjects

0301 basic medicine, Models, Molecular, Protein Folding, Stereochemistry, Protein Conformation, Recombinant Fusion Proteins, Population, Amino Acid Motifs, Lyases, Heme, Protein Engineering, Biochemistry, environment and public health, Article, Conserved sequence, 03 medical and health sciences, chemistry.chemical_compound, Protein structure, Humans, Amino Acid Sequence, Cysteine, education, Peptide sequence, Conserved Sequence, Glutathione Transferase, education.field_of_study, biology, Cytochrome c, Circular Dichroism, Cytochromes c, Stereoisomerism, HCCS, Oxygen, enzymes and coenzymes (carbohydrates), 030104 developmental biology, chemistry, Amino Acid Substitution, embryonic structures, Mutation, biology.protein, cardiovascular system, Mutagenesis, Site-Directed

Abstract

C-type cytochromes (cyts c) are generally characterized by the presence of two thioether attachments between heme and two cysteine residues within a highly conserved CXXCH motif. Most eukaryotes use the System III cyt c biogenesis pathway composed of holocytochrome c synthase (HCCS) to catalyze thioether formation. Some protozoan organisms express a functionally equivalent, natural variant of cyt c with an XXXCH heme-attachment motif, resulting in a single covalent attachment. Previous studies have shown that recombinant HCCS can produce low levels of the XXXCH single thioether variant. However, cyt c variants containing substitutions at the C-terminal cysteine of the heme-attachment site (i.e., resulting in CXXXH) have never been observed in nature, and attempts to biosynthesize a recombinant version of this cyt c variant have been largely unsuccessful. In this study, we report the biochemical analyses of an HCCS-matured CXXXH cyt c variant, comparing its biosynthesis and properties to those of the XXXCH variant. The results indicate that although HCCS mediates heme attachment to the N-terminal cysteine in CXXXH cyt c variants, up to 50% of the cyt c produced is modified in an oxygen-dependent manner, resulting in a mixed population of cyt c. Since this aerobic modification occurs only in the context of CXXXH, we also propose that natural HCCS-mediated heme attachment to CXXCH likely initiates at the C-terminal cysteine.

Published

2017

14. Mechanisms of Mitochondrial Holocytochrome c Synthase and the Key Roles Played by Cysteines and Histidine of the Heme Attachment Site, Cys-XX-Cys-His

Author

Brian San Francisco, Gudrun S. Lukat-Rodgers, Eric C. Bretsnyder, Kenton R. Rodgers, Shalon E. Babbitt, Robert G. Kranz, and Deanna L. Mendez

Subjects

Protein Folding, Pyridines, Stereochemistry, Oligonucleotides, Lyases, Heme, Ligands, Spectrum Analysis, Raman, Biochemistry, chemistry.chemical_compound, Catalytic Domain, Escherichia coli, Humans, Histidine, Cysteine, Sulfhydryl Compounds, Binding site, neoplasms, Molecular Biology, Conserved Sequence, Binding Sites, biology, Chemistry, Ligand, Cytochrome c, Cytochromes c, Active site, Cell Biology, HCCS, digestive system diseases, Mitochondria, Enzymology, biology.protein, Spectrophotometry, Ultraviolet, Plasmids

Abstract

Mitochondrial cytochrome c assembly requires the covalent attachment of heme by thioether bonds between heme vinyl groups and a conserved CXXCH motif of cytochrome c/c1. The enzyme holocytochrome c synthase (HCCS) binds heme and apocytochrome c substrate to catalyze this attachment, subsequently releasing holocytochrome c for proper folding to its native structure. We address mechanisms of assembly using a functional Escherichia coli recombinant system expressing human HCCS. Human cytochrome c variants with individual cysteine, histidine, double cysteine, and triple cysteine/histidine substitutions (of CXXCH) were co-purified with HCCS. Single and double mutants form a complex with HCCS but not the triple mutant. Resonance Raman and UV-visible spectroscopy support the proposal that heme puckering induced by both thioether bonds facilitate release of holocytochrome c from the complex. His-19 (of CXXCH) supplies the second axial ligand to heme in the complex, the first axial ligand was previously shown to be from HCCS residue His-154. Substitutions of His-19 in cytochrome c to seven other residues (Gly, Ala, Met, Arg, Lys, Cys, and Tyr) were used with various approaches to establish other roles played by His-19. Three roles for His-19 in HCCS-mediated assembly are suggested: (i) to provide the second axial ligand to the heme iron in preparation for covalent attachment; (ii) to spatially position the two cysteinyl sulfurs adjacent to the two heme vinyl groups for thioether formation; and (iii) to aid in release of the holocytochrome c from the HCCS active site. Only H19M is able to carry out these three roles, albeit at lower efficiencies than the natural His-19.

Published

2014

15. Conserved Residues of the Human Mitochondrial Holocytochrome c Synthase Mediate Interactions with Heme

Author

Eric C. Bretsnyder, Robert G. Kranz, Shalon E. Babbitt, and Brian San Francisco

Subjects

Models, Molecular, Heme binding, Cytochrome, Protein Conformation, Mitochondrial intermembrane space, Molecular Sequence Data, Lyases, Heme, Biochemistry, Gene Expression Regulation, Enzymologic, Article, Cofactor, Conserved sequence, 03 medical and health sciences, chemistry.chemical_compound, Humans, Amino Acid Sequence, neoplasms, Conserved Sequence, 030304 developmental biology, 0303 health sciences, biology, Cytochrome c, 030302 biochemistry & molecular biology, HCCS, digestive system diseases, Protein Structure, Tertiary, chemistry, Mutation, biology.protein, Protein Binding

Abstract

C-type cytochromes are distinguished by the covalent attachment of a heme cofactor, a modification that is typically required for its subsequent folding, stability, and function. Heme attachment takes place in the mitochondrial intermembrane space and, in most eukaryotes, is mediated by holocytochrome c synthase (HCCS). HCCS is the primary component of the eukaryotic cytochrome c biogenesis pathway, known as System III. The catalytic function of HCCS depends on its ability to coordinate interactions between its substrates: heme and cytochrome c. Recent advancements in the recombinant expression and purification of HCCS have facilitated comprehensive analyses of the roles of conserved residues in HCCS, as demonstrated in this study. Previously, we proposed a four-step model describing HCCS-mediated cytochrome c assembly, identifying a conserved histidine residue (His154) as an axial ligand to the heme iron. In this study, we performed a systematic mutational analysis of 17 conserved residues in HCCS, and we provide evidence that the enzyme contains two heme-binding domains. Our data indicate that heme contacts mediated by residues within these domains modulate the dynamics of heme binding and contribute to the stability of the HCCS–heme–cytochrome c steady state ternary complex. While some residues are essential for initial heme binding (step 1), others impact the subsequent release of the holocytochrome c product (step 4). Certain HCCS mutants that were defective in heme binding were corrected for function by exogenous aminolevulinic acid (ALA, the precursor to heme). This chemical “correction” supports the proposed role of heme binding for the corresponding residues.

Published

2014

16. The CcmFH complex is the system I holocytochromecsynthetase: engineering cytochromecmaturation independent of CcmABCDE

Author

Brian San Francisco, Robert G. Kranz, and Molly C. Sutherland

Subjects

Signal peptide, Cytochrome, Cytochrome c, Periplasmic space, Biology, Microbiology, Conserved sequence, chemistry.chemical_compound, chemistry, Biochemistry, biology.protein, Cytochrome c oxidase, Thioredoxin, Molecular Biology, Heme

Abstract

Cytochrome c maturation (ccm) in many bacteria, archaea and plant mitochondria requires eight membrane proteins, CcmABCDEFGH, called system I. This pathway delivers and attaches haem covalently to two cysteines (of Cys-Xxx-Xxx-Cys-His) in the cytochrome c. All models propose that CcmFH facilitates covalent attachment of haem to the apocytochrome; namely, that it is the synthetase. However, holocytochrome c synthetase activity has not been directly demonstrated for CcmFH. We report formation of holocytochromes c by CcmFH and CcmG, a periplasmic thioredoxin, independent of CcmABCDE (we term this activity CcmFGH-only). Cytochrome c produced in the absence of CcmABCDE is indistinguishable from cytochrome c produced by the full system I, with a cleaved signal sequence and two covalent bonds to haem. We engineered increased cytochrome c production by CcmFGH-only, with yields approaching those from the full system I. Three conserved histidines in CcmF (TM-His1, TM-His2 and P-His1) are required for activity, as are the conserved cysteine pairs in CcmG and CcmH. Our findings establish that CcmFH is the system I holocytochrome c synthetase. Although we discuss why this engineering would likely not replace the need for CcmABCDE in nature, these results provide unique mechanistic and evolutionary insights into cytochrome c biosynthesis.

Published

2014

17. Engineered holocytochrome c synthases that biosynthesize new cytochromes c

Author

John M. D’Alessandro, Robert G. Kranz, Jeremy D. King, Deanna L. Mendez, Shalon E. Babbitt, Liviu M. Mirica, Michael B. Watson, and Robert E. Blankenship

Subjects

0301 basic medicine, Circular dichroism, Stereochemistry, Amino Acid Motifs, Coenzymes, Gene Expression, Lyases, Context (language use), Heme, Protein Engineering, environment and public health, Protein Structure, Secondary, Substrate Specificity, Electron Transport, 03 medical and health sciences, chemistry.chemical_compound, Catalytic Domain, Escherichia coli, Humans, Protein Interaction Domains and Motifs, Cloning, Molecular, Histidine, Multidisciplinary, biology, Ligand, Chemistry, Cytochrome c, Active site, Cytochromes c, HCCS, Biological Sciences, digestive system diseases, Recombinant Proteins, enzymes and coenzymes (carbohydrates), 030104 developmental biology, Amino Acid Substitution, embryonic structures, Mutation, biology.protein, cardiovascular system, Oxidation-Reduction, Protein Binding

Abstract

Cytochrome c (cyt c), required for electron transport in mitochondria, possesses a covalently attached heme cofactor. Attachment is catalyzed by holocytochrome c synthase (HCCS), leading to two thioether bonds between heme and a conserved CXXCH motif of cyt c In cyt c, histidine (His19) of CXXCH acts as an axial ligand to heme iron and upon release of holocytochrome c from HCCS, folding leads to formation of a second axial interaction with methionine (Met81). We previously discovered mutations in human HCCS that facilitate increased biosynthesis of cyt c in recombinant Escherichia coli Focusing on HCCS E159A, novel cyt c variants in quantities that are sufficient for biophysical analysis are biosynthesized. Cyt c H19M, the first bis-Met liganded cyt c, is compared with other axial ligand variants (M81A, M81H) and single thioether cyt c variants. For variants with axial ligand substitutions, electronic absorption, near-UV circular dichroism, and electron paramagnetic resonance spectroscopy provide evidence that axial ligands are changed and the heme environment is altered. Circular dichroism spectra in far UV and thermal denaturation analyses demonstrate that axial ligand changes do not affect secondary structures and stability. Redox potentials span a 400-mV range (+349 mV vs. standard hydrogen electrode, H19M; +252 mV, WT; -19 mV, M81A; -69 mV, M81H). We discuss the results in the context of a four-step mechanism for HCCS, whereby HCCS mutants such as E159A are enhanced in release (step 4) of cyt c from the HCCS active site; thus, we term these "release mutants."

Published

2017

18. A Nitrogen-Regulated Glutamine Amidotransferase (GAT1_2.1) Represses Shoot Branching in Arabidopsis

Author

Huifen Zhu and Robert G. Kranz

Subjects

Nitrogen, Physiology, Nitrogenous Group Transferases, Research Articles - Focus Issue, Molecular Sequence Data, Mutant, Arabidopsis, Strigolactone, Plant Science, Biology, Genes, Plant, Models, Biological, Gene Expression Regulation, Enzymologic, Lactones, chemistry.chemical_compound, Quantitative Trait, Heritable, Biosynthesis, Gene Expression Regulation, Plant, Morphogenesis, Genetics, Arabidopsis thaliana, Amino Acid Sequence, Gene, Psychological repression, Phylogeny, Transaminases, Glutamine amidotransferase, Arabidopsis Proteins, biology.organism_classification, Phenotype, Biochemistry, chemistry, Mutation, Sequence Alignment, Plant Shoots

Abstract

Shoot branching in plants is regulated by many environmental cues and by specific hormones such as strigolactone (SL). We show that the GAT1_2.1 gene (At1g15040) is repressed over 50-fold by nitrogen stress, and is also involved in branching control. At1g15040 is predicted to encode a class I glutamine amidotransferase (GAT1), a superfamily for which Arabidopsis (Arabidopsis thaliana) has 30 potential members. Most members can be categorized into known biosynthetic pathways, for the amidation of known acceptor molecules (e.g. CTP synthesis). Some members, like GAT1_2.1, are of unknown function, likely involved in amidation of unknown acceptors. A gat1_2.1 mutant exhibits a significant increase in shoot branching, similar to mutants in SL biosynthesis. The results suggest that GAT1_2.1 is not involved in SL biosynthesis since exogenously applied GR24 (a synthetic SL) does not correct the mutant phenotype. The subfamily of GATs (GATase1_2), with At1g15040 as the founding member, appears to be present in all plants (including mosses), but not other organisms. This suggests a plant-specific function such as branching control. We discuss the possibility that the GAT1_2.1 enzyme may activate SLs (e.g. GR24) by amidation, or more likely could embody a new pathway for repression of branching.

Published

2012

19. Heme Ligand Identification and Redox Properties of the Cytochrome c Synthetase, CcmF

Author

Robert G. Kranz, Brian San Francisco, Kenton R. Rodgers, and Eric C. Bretsnyder

Subjects

Models, Molecular, Protein Conformation, Stereochemistry, Lyases, Context (language use), Heme, Ligands, Spectrum Analysis, Raman, Biochemistry, Article, chemistry.chemical_compound, Protein structure, Histidine, Integral membrane protein, Phylogeny, Binding Sites, biology, Ligand, Escherichia coli Proteins, Cytochrome c, Imidazoles, Recombinant Proteins, Transmembrane protein, Enzyme Activation, Protein Subunits, Amino Acid Substitution, chemistry, Biocatalysis, biology.protein, Indicators and Reagents, Mutant Proteins, Holoenzymes, Oxidation-Reduction

Abstract

Cytochrome c maturation in many bacteria, archaea, and plant mitochondria involves the integral membrane protein CcmF, which is thought to function as a cytochrome c synthetase by facilitating the final covalent attachment of heme to the apocytochrome c. We previously reported that the E. coli CcmF protein contains a b-type heme that is stably and stoichiometrically associated with the protein and is not the heme attached to apocytochrome c. Here, we show that mutation of either of two conserved transmembrane histidines (His261 or His491) impairs stoichiometric b-heme binding in CcmF and results in spectral perturbations in the remaining heme. Exogeneous imidazole is able to correct cytochrome c maturation for His261 and His491 substitutions with small side chains (Ala or Gly), suggesting that a "cavity" is formed in these CcmF mutants in which imidazole binds and acts as a functional ligand to the b-heme. The results of resonance Raman spectroscopy on wild-type CcmF are consistent with a hexacoordinate low-spin b-heme with at least one endogeneous axial His ligand. Analysis of purified recombinant CcmF proteins from diverse prokaryotes reveals that the b-heme in CcmF is widely conserved. We have also determined the reduction potential of the CcmF b-heme (E(m,7) = -147 mV). We discuss these results in the context of CcmF structure and functions as a heme reductase and cytochrome c synthetase.

Published

2011

20. Substrate specificity of three cytochromechaem lyase isoenzymes fromWolinella succinogenes: unconventional haemcbinding motifs are not sufficient for haemcattachment by NrfI and CcsA1

Author

Robert G. Kranz, Jörg Simon, Florian Eisel, Melanie Kern, and Juliane Scheithauer

Subjects

Cytochrome, Amino Acid Motifs, Lyases, Heme, medicine.disease_cause, Microbiology, Campylobacter jejuni, Article, Substrate Specificity, chemistry.chemical_compound, Bacterial Proteins, Escherichia coli, medicine, Binding site, Molecular Biology, Binding Sites, biology, Cytochrome c, biology.organism_classification, Nitrite reductase, Lyase, Wolinella, Isoenzymes, chemistry, Biochemistry, biology.protein

Abstract

Bacterial c-type cytochrome maturation is dependent on a complex enzymic machinery. The key reaction is catalysed by cytochrome c haem lyase (CCHL) that usually forms two thioether bonds to attach haem b to the cysteine residues of a haem c binding motif (HBM) which is, in most cases, a CX(2)CH sequence. Here, the HBM specificity of three distinct CCHL isoenzymes (NrfI, CcsA1 and CcsA2) from the Epsilonproteobacterium Wolinella succinogenes was investigated using either W. succinogenes or Escherichia coli as host organism. Several reporter c-type cytochromes were employed including cytochrome c nitrite reductases (NrfA) from E. coli and Campylobacter jejuni that differ in their active-site HBMs (CX(2)CK or CX(2)CH). W. succinogenes CcsA2 was found to attach haem to standard CX(2)CH motifs in various cytochromes whereas other HBMs were not recognized. NrfI was able to attach haem c to the active-site CX(2)CK motif of both W. succinogenes and E. coli NrfA, but not to NrfA from C. jejuni. Different apo-cytochrome variants carrying the CX(15)CH motif, assumed to be recognized by CcsA1 during maturation of the octahaem cytochrome MccA, were not processed by CcsA1 in either W. succinogenes or E. coli. It is concluded that the dedicated CCHLs NrfI and CcsA1 attach haem to non-standard HBMs only in the presence of further, as yet uncharacterized structural features. Interestingly, it proved impossible to delete the ccsA2 gene from the W. succinogenes genome, a finding that is discussed in the light of the available genomic, proteomic and functional data on W. succinogenes c-type cytochromes.

Published

2010

21. Essential histidine pairs indicate conserved haem binding in epsilonproteobacterial cytochrome c haem lyases

Author

Melanie Kern, Jörg Simon, Robert G. Kranz, and Juliane Scheithauer

Subjects

Amino Acid Motifs, Lyases, Heme, Biology, medicine.disease_cause, Microbiology, Conserved sequence, 03 medical and health sciences, chemistry.chemical_compound, Bacterial Proteins, medicine, Histidine, Binding site, Escherichia coli, Conserved Sequence, 030304 developmental biology, Alanine, 0303 health sciences, Binding Sites, 030306 microbiology, Cytochrome c, digestive, oral, and skin physiology, Lyase, Wolinella, Biochemistry, chemistry, biology.protein, Physiology and Biochemistry

Abstract

Bacterial cytochrome c maturation occurs at the outside of the cytoplasmic membrane, requires transport of haem b across the membrane, and depends on membrane-bound cytochrome c haem lyase (CCHL), an enzyme that catalyses covalent attachment of haem b to apocytochrome c. Epsilonproteobacteria such as Wolinella succinogenes use the cytochrome c biogenesis system II and contain unusually large CCHL proteins of about 900 amino acid residues that appear to be fusions of the CcsB and CcsA proteins found in other bacteria. CcsBA-type CCHLs have been proposed to act as haem transporters that contain two haem b coordination sites located at different sides of the membrane and formed by histidine pairs. W. succinogenes cells contain three CcsBA-type CCHL isoenzymes (NrfI, CcsA1 and CcsA2) that are known to differ in their specificity for apocytochromes and apparently recognize different haem c binding motifs such as CX2CH (by CcsA2), CX2CK (by NrfI) and CX15CH (by CcsA1). In this study, conserved histidine residues were individually replaced by alanine in each of the W. succinogenes CCHLs. Characterization of NrfI and CcsA1 variants in W. succinogenes demonstrated that a set of four histidines is essential for maturing the dedicated multihaem cytochromes c NrfA and MccA, respectively. The function of W. succinogenes CcsA2 variants produced in Escherichia coli was also found to depend on each of these four conserved histidine residues. The presence of imidazole in the growth medium of both W. succinogenes and E. coli rescued the cytochrome c biogenesis activity of most histidine variants, albeit to different extents, thereby implying the presence of two functionally distinct histidine pairs in each CCHL. The data support a model in which two conserved haem b binding sites are involved in haem transport catalysed by CcsBA-type CCHLs.

Published

2010

22. Cytochrome c Biogenesis: Mechanisms for Covalent Modifications and Trafficking of Heme and for Heme-Iron Redox Control

Author

Elaine R. Frawley, Cynthia L. Richard-Fogal, John-Stephen Taylor, and Robert G. Kranz

Subjects

Hemeprotein, Heme binding, Stereochemistry, Iron, Reviews, Cytochrome c Group, Heme, Microbiology, Cofactor, chemistry.chemical_compound, Animals, Humans, Molecular Biology, Integral membrane protein, chemistry.chemical_classification, biology, Cytochrome c, Conjugated protein, Biosynthetic Pathways, Transport protein, Protein Transport, Infectious Diseases, chemistry, Biochemistry, biology.protein, Oxidation-Reduction, Protein Processing, Post-Translational

Abstract

SUMMARY Heme is the prosthetic group for cytochromes, which are directly involved in oxidation/reduction reactions inside and outside the cell. Many cytochromes contain heme with covalent additions at one or both vinyl groups. These include farnesylation at one vinyl in hemes o and a and thioether linkages to each vinyl in cytochrome c (at CXXCH of the protein). Here we review the mechanisms for these covalent attachments, with emphasis on the three unique cytochrome c assembly pathways called systems I, II, and III. All proteins in system I (called Ccm proteins) and system II (Ccs proteins) are integral membrane proteins. Recent biochemical analyses suggest mechanisms for heme channeling to the outside, heme-iron redox control, and attachment to the CXXCH. For system II, the CcsB and CcsA proteins form a cytochrome c synthetase complex which specifically channels heme to an external heme binding domain; in this conserved tryptophan-rich “WWD domain” (in CcsA), the heme is maintained in the reduced state by two external histidines and then ligated to the CXXCH motif. In system I, a two-step process is described. Step 1 is the CcmABCD-mediated synthesis and release of oxidized holoCcmE (heme in the Fe +3 state). We describe how external histidines in CcmC are involved in heme attachment to CcmE, and the chemical mechanism to form oxidized holoCcmE is discussed. Step 2 includes the CcmFH-mediated reduction (to Fe +2 ) of holoCcmE and ligation of the heme to CXXCH. The evolutionary and ecological advantages for each system are discussed with respect to iron limitation and oxidizing environments.

Published

2009

23. A conserved haem redox and trafficking pathway for cofactor attachment

Author

Eric R Bonner, Elaine R. Frawley, Brian San Francisco, Huifen Zhu, Robert G. Kranz, and Cynthia L. Richard-Fogal

Subjects

Hemeproteins, Cytochrome, Iron, Haem peroxidase, Lyases, Heme, Plasma protein binding, Article, General Biochemistry, Genetics and Molecular Biology, Cofactor, chemistry.chemical_compound, Oxidoreductase, Escherichia coli, polycyclic compounds, Amino Acid Sequence, Molecular Biology, chemistry.chemical_classification, Binding Sites, General Immunology and Microbiology, biology, Cytochrome b, Escherichia coli Proteins, General Neuroscience, Cytochrome c, digestive, oral, and skin physiology, Cytochromes c, Hydroquinones, chemistry, Biochemistry, biology.protein, Oxidation-Reduction, Bacterial Outer Membrane Proteins, Protein Binding

Abstract

A pathway for cytochrome c maturation (Ccm) in bacteria, archaea and eukaryotes (mitochondria) requires the genes encoding eight membrane proteins (CcmABCDEFGH). The CcmABCDE proteins are proposed to traffic haem to the cytochrome c synthetase (CcmF/H) for covalent attachment to cytochrome c by unknown mechanisms. For the first time, we purify pathway complexes with trapped haem to elucidate the molecular mechanisms of haem binding, trafficking and redox control. We discovered an early step in trafficking that involves oxidation of haem (to Fe(3+)), yet the final attachment requires reduced haem (Fe(2+)). Surprisingly, CcmF is a cytochrome b with a haem never before realized, and in vitro, CcmF functions as a quinol:haem oxidoreductase. Thus, this ancient pathway has conserved and orchestrated mechanisms for trafficking, storing and reducing haem, which assure its use for cytochrome c synthesis even in limiting haem (iron) environments and reducing haem in oxidizing environments.

Published

2009

24. CPC, a Single-Repeat R3 MYB, Is a Negative Regulator of Anthocyanin Biosynthesis in Arabidopsis

Author

Abha Khandelwal, Huifen Zhu, Robert G. Kranz, and Karen Fitzsimmons

Subjects

Molecular Sequence Data, Arabidopsis, Regulator, Pancreatitis-Associated Proteins, macromolecular substances, Plant Science, Root hair, Models, Biological, Anthocyanins, Proto-Oncogene Proteins c-myb, Gene Expression Regulation, Plant, Gene expression, MYB, Amino Acid Sequence, Transcription factor, Molecular Biology, Regulation of gene expression, Sequence Homology, Amino Acid, biology, Arabidopsis Proteins, Reverse Transcriptase Polymerase Chain Reaction, fungi, technology, industry, and agriculture, food and beverages, Plants, Genetically Modified, biology.organism_classification, Flavonoid biosynthesis, Biochemistry

Abstract

Single-repeat R3 MYB transcription factors like CPC (CAPRICE) are known to play roles in developmental processes such as root hair differentiation and trichome initiation. However, none of the six Arabidopsis single-repeat R3 MYB members has been reported to regulate flavonoid biosynthesis. We show here that CPC is a negative regulator of anthocyanin biosynthesis. In the process of using CPC to test GAL4-dependent driver lines, we observed a repression of anthocyanin synthesis upon GAL4-mediated CPC overexpression. We demonstrated that this is not due to an increase in nutrient uptake because of more root hairs. Rather, CPC expression level tightly controls anthocyanin accumulation. Microarray analysis on the whole genome showed that, of 37 000 features tested, 85 genes are repressed greater than three-fold by CPC overexpression. Of these 85, seven are late anthocyanin biosynthesis genes. Also, anthocyanin synthesis genes were shown to be down-regulated in 35S::CPC overexpression plants. Transient expression results suggest that CPC competes with the R2R3-MYB transcription factor PAP1/2, which is an activator of anthocyanin biosynthesis genes. This report adds anthocyanin biosynthesis to the set of programs that are under CPC control, indicating that this regulator is not only for developmental programs (e.g. root hairs, trichomes), but can influence anthocyanin pigment synthesis.

Published

2009

25. The Cytochrome c Maturation Components CcmF, CcmH, and CcmI Form a Membrane-integral Multisubunit Heme Ligation Complex

Author

Özlem Önder, Fevzi Daldal, Serdar Turkarslan, Robert G. Kranz, Carsten Sanders, and Dong Woo Lee

Subjects

Detergents, Mutant, Heme, medicine.disease_cause, Models, Biological, Biochemistry, Chromatography, Affinity, Rhodobacter capsulatus, Epitopes, chemistry.chemical_compound, Protein structure, Affinity chromatography, medicine, Photosynthesis, Molecular Biology, Chromatography, Mutation, Rhodobacter, biology, Cytochrome c, Cell Membrane, Cytochromes c, Cell Biology, biology.organism_classification, Protein Structure, Tertiary, Metabolism and Bioenergetics, Genetic Techniques, chemistry, Protein modification process, Multiprotein Complexes, biology.protein, Plasmids

Abstract

Cytochrome c maturation (Ccm) is a post-translational and post-export protein modification process that involves ten (CcmABCDEFGHI and CcdA or DsbD) components in most Gram-negative bacteria. The absence of any of these components abolishes the ability of cells to form cytochrome c, leading in the case of Rhodobacter capsulatus to the loss of photosynthetic proficiency and respiratory cytochrome oxidase activity. Based on earlier molecular genetic studies, we inferred that R. capsulatus CcmF, CcmH, and CcmI interact with each other to perform heme-apocytochrome c ligation. Here, using functional epitope-tagged derivatives of these components coproduced in appropriate mutant strains, we determined protein-protein interactions between them in detergent-dispersed membranes. Reciprocal affinity purification as well as tandem size exclusion and affinity chromatography analyses provided the first biochemical evidence that CcmF, CcmH, and CcmI associate stably with each other, indicating that these Ccm components form a membrane-integral complex. Under the conditions used, the CcmFHI complex does not contain CcmG, suggesting that the latter thio-reduction component is not always associated with the heme ligation components. The findings are discussed with respect to defining the obligatory components of a minimalistic heme-apocytochrome c ligation complex in R. capsulatus.

Published

2008

26. Heme Concentration Dependence and Metalloporphyrin Inhibition of the System I and II Cytochrome c Assembly Pathways

Author

Robert E. Feissner, Elaine R. Frawley, Robert G. Kranz, and Cynthia L. Richard-Fogal

Subjects

Heme binding, Metalloporphyrins, Physiology and Metabolism, Protoporphyrins, Cytochrome c Group, Heme, Biology, medicine.disease_cause, Models, Biological, Microbiology, chemistry.chemical_compound, polycyclic compounds, Escherichia coli, medicine, Molecular Biology, Escherichia coli Proteins, Cytochrome c, Gene Expression Regulation, Bacterial, Porphyrin, Biochemistry, chemistry, Mutation, biology.protein, Protoporphyrin, Biogenesis, Signal Transduction

Abstract

Studies have indicated that specific heme delivery to apocytochrome c is a critical feature of the cytochrome c biogenesis pathways called system I and II. To determine directly the heme requirements of each system, including whether other metal porphyrins can be incorporated into cytochromes c , we engineered Escherichia coli so that the natural system I ( ccmABCDEFGH ) was deleted and exogenous porphyrins were the sole source of porphyrins (Δ hemA ). The engineered E. coli strains that produced recombinant system I (from E. coli ) or system II (from Helicobacter ) facilitated studies of the heme concentration dependence of each system. Using this exogenous porphyrin approach, it was shown that in system I the levels of heme used are at least fivefold lower than the levels used in system II, providing an important advantage for system I. Neither system could assemble holocytochromes c with other metal porphyrins, suggesting that the attachment mechanism is specific for Fe protoporphyrin. Surprisingly, Zn and Sn protoporphyrins are potent inhibitors of the pathways, and exogenous heme competes with this inhibition. We propose that the targets are the heme binding proteins in the pathways (CcmC, CcmE, and CcmF for system I and CcsA for system II).

Published

2007

27. Mitochondrial cytochrome c biogenesis: no longer an enigma

Author

Shalon E. Babbitt, Brian San Francisco, Robert G. Kranz, Deanna L. Mendez, and Molly C. Sutherland

Subjects

Hemeprotein, biology, Cellular respiration, Cytochrome c, Cytochromes c, Lyases, Mitochondrion, HCCS, Biochemistry, Article, Cell biology, Mitochondria, chemistry.chemical_compound, chemistry, Apoptosis, biology.protein, Animals, Humans, Molecular Biology, Heme, Biogenesis

Abstract

Cytochromes c (cyt c) and c1 are heme proteins that are essential for aerobic respiration. Release of cyt c from mitochondria is an important signal in apoptosis initiation. Biogenesis of c-type cytochromes involves covalent attachment of heme to two cysteines (at a conserved CXXCH sequence) in the apocytochrome. Heme attachment is catalyzed in most mitochondria by holocytochrome c synthase (HCCS), which is also necessary for the import of apocytochrome c (apocyt c). Thus, HCCS affects cellular levels of cyt c, impacting mitochondrial physiology and cell death. Here, we review the mechanisms of HCCS function and the roles of heme and residues in the CXXCH motif. Additionally, we consider concepts emerging within the two prokaryotic cytochrome c biogenesis pathways.

Published

2015

28. ABC transporter-mediated release of a haem chaperone allows cytochromecbiogenesis

Author

Cynthia L. Richard-Fogal, Robert E. Feissner, Elaine R. Frawley, and Robert G. Kranz

Subjects

Protein subunit, Cytochrome c, digestive, oral, and skin physiology, Transporter, ATP-binding cassette transporter, Periplasmic space, Biology, Microbiology, Membrane protein, Biochemistry, Chaperone (protein), biology.protein, Molecular Biology, Biogenesis

Abstract

Although organisms from all kingdoms have either the system I or II cytochrome c biogenesis pathway, it has remained a mystery as to why these two distinct pathways have developed. We have previously shown evidence that the system I pathway has a higher affinity for haem than system II for cytochrome c biogenesis. Here, we show the mechanism by which the system I pathway can utilize haem at low levels. The mechanism involves an ATP-binding cassette (ABC) transporter that is required for release of the periplasmic haem chaperone CcmE to the last step of cytochrome c assembly. This ABC transporter is composed of the ABC subunit CcmA, and two membrane proteins, CcmB and CcmC. In the absence of CcmA or CcmB, holo(haem)CcmE binds to CcmC in a stable dead-end complex, indicating high affinity binding of haem to CcmC. Expression of CcmA and CcmB facilitates formation of the CcmA 2 B 1 C 1 complex and ATP-dependent release of holoCcmE. We propose that the CcmA 2 B 1 C 1 complex represents a new subgroup within the ABC transporter superfamily that functions to release a chaperone.

Published

2006

29. Overproduction of CcmG and CcmFH Rc Fully Suppresses the c -Type Cytochrome Biogenesis Defect of Rhodobacter capsulatus CcmI-Null Mutants

Author

Robert G. Kranz, Fevzi Daldal, Meenal Deshmukh, Doniel Astor, and Carsten Sanders

Subjects

Physiology and Metabolism, Mutant, environment and public health, Microbiology, Rhodobacter capsulatus, chemistry.chemical_compound, Suppression, Genetic, Bacterial Proteins, Promoter Regions, Genetic, Overproduction, Molecular Biology, Heme, Rhodobacter, biology, Cytochrome c, Cytochromes c, Gene Expression Regulation, Bacterial, Periplasmic space, biology.organism_classification, enzymes and coenzymes (carbohydrates), chemistry, Biochemistry, Chaperone (protein), embryonic structures, cardiovascular system, biology.protein, Biogenesis, Plasmids

Abstract

Gram-negative bacteria like Rhodobacter capsulatus use intertwined pathways to carry out the posttranslational maturation of c -type cytochromes (Cyts). This periplasmic process requires at least 10 essential components for apo-Cyt c chaperoning, thio-oxidoreduction, and the delivery of heme and its covalent ligation. One of these components, CcmI (also called CycH), is thought to act as an apo-Cyt c chaperone. In R. capsulatus , CcmI-null mutants are unable to produce c -type Cyts and thus sustain photosynthetic (Ps) growth. Previously, we have shown that overproduction of the putative heme ligation components CcmF and CcmH Rc (also called Ccl1 and Ccl2) can partially bypass the function of CcmI on minimal, but not on enriched, media. Here, we demonstrate that either additional overproduction of CcmG (also called HelX) or hyperproduction of CcmF-CcmH Rc is needed to completely overcome the role of CcmI during the biogenesis of c -type Cyts on both minimal and enriched media. These findings indicate that, in the absence of CcmI, interactions between the heme ligation and thioreduction pathways become restricted for sufficient Cyt c production. We therefore suggest that CcmI, along with its apo-Cyt chaperoning function, is also critical for the efficacy of holo-Cyt c formation, possibly via its close interactions with other components performing the final heme ligation steps during Cyt c biogenesis.

Published

2005

30. Heme Trafficking by the Cytochrome C Biogenesis Pathways

Author

Molly C. Sutherland, Joel A Rankin, and Robert G. Kranz

Subjects

Hemeprotein, biology, Cytochrome c, Biophysics, Periplasmic space, Electron transport chain, Cell biology, chemistry.chemical_compound, Biochemistry, chemistry, Membrane protein, biology.protein, Integral membrane protein, Heme, Biogenesis

Abstract

Cytochromes function in electron transport chains to perform critical cellular functions, such as respiration and photosynthesis. Cytochromes c are unique due to their requirement for the covalent attachment of heme via two thioether bonds at a conserved CXXCH motif. Three pathways have been identified for cytochrome c maturation: System I (prokaryotes), System II (prokaryotes) and System III (eukaryotes). System I consists of 8 integral membrane proteins (CcmABCDEFGH), System II is comprised of 2 membrane proteins (CcsBA) and these pathways will be the focus of this presentation. Trafficking of heme from the site of its synthesis (cytoplasm) to the site of attachment to apocytochrome c (periplasm) is critical for cytochrome c biogenesis, yet little direct evidence of heme trafficking exists. The study of heme trafficking has proved elusive in this and most other systems due to tight cellular regulation, as well as the cytotoxic and amphipathic nature of heme. Here, we use key putative heme transporters in the prokaryotic pathways as model systems to develop a novel technique to covalently ‘trap’ heme during the trafficking process. First, the conserved WWD domain, which is predicted to interact with heme in the periplasmic space and is found in both System I and System II pathways, was used to develop the heme trapping technique. Heme was covalently trapped in the WWD domains of CcmC (System I) and CcsA (System II), providing the first direct evidence of how heme is trafficked to the periplasm in cytochrome c biogenesis. Currently, this trapping approach is being used on other integral membrane proteins in the pathway to capture heme intermediates and delineate the exact paths for trafficking in vivo. We envision that this approach will be applicable to other heme transporters and trafficking pathways from prokaryotes through eukaryotes.

Published

2017

31. RNA Polymerase Subunit Requirements for Activation by the Enhancer-binding Protein Rhodobacter capsulatus NtrC

Author

Animesh Tandon, Robert G. Kranz, Cynthia L. Richard, and Nathaniel R. Sloan

Subjects

DNA, Bacterial, Transcriptional Activation, PII Nitrogen Regulatory Proteins, Specificity factor, RNA-dependent RNA polymerase, RNA polymerase II, Biochemistry, Rhodobacter capsulatus, chemistry.chemical_compound, Bacterial Proteins, RNA polymerase, RNA polymerase I, Promoter Regions, Genetic, Molecular Biology, Polymerase, Base Sequence, biology, Escherichia coli Proteins, DNA-Directed RNA Polymerases, Cell Biology, DNA-Binding Proteins, Enzyme Activation, chemistry, Trans-Activators, biology.protein, Transcription factor II D, Small nuclear RNA, Transcription Factors

Abstract

Rhodobacter capsulatus NtrC is an enhancer-binding protein that activates transcription of the R. capsulatus sigma 70 RNA polymerase, but does not activate the Escherichia coli sigma 70-RNA polymerase at the nifA1 promoter. We utilized R. capsulatus:E. coli hybrid RNA polymerases assembled in vitro to investigate the subunits required for protein-protein interaction with RcNtrC at the nifA1mut1 promoter. Assembly of core Rc alpha beta beta' or hybrid RNA polymerases containing the Rc beta beta' subunits absolutely require the inclusion of an omega subunit, with the Ec omega subunit only partially promoting RNA polymerase assembly. The Rc alpha Ec beta beta' RNA polymerase is not activated by RcNtrC. Moreover, a mutant form of the Rc alpha lacking the alpha C-terminal domain, when assembled with the Rc beta beta'omega and sigma 70 subunits, is activated by RcNtrC. These results suggest that the R. capsulatus alpha subunit is not important for RcNtrC interaction. All hybrid RNA polymerases that contained the Rc beta' were activated by RcNtrC, suggesting that the Rc beta' subunit plays an important role. It is proposed that RcNtrC recruits R. capsulatus sigma 70-RNA polymerase to the promoter through interaction with Rc beta'. RcNtrC interacts with RNA polymerase from a unique position, with dimers centered at -118 bp from the start site. Placing the RcNtrC tandem binding sites on the opposite face of the helix (-113 bp) completely abolished transcription activation. Moving the RcNtrC tandem binding sites 20 bp closer to or further from the promoter significantly reduced activation, again suggesting unique spatial constraints on how RcNtrC interacts with the R. capsulatus RNA polymerase.

Published

2003

32. Overexpression of ccl1−2 can bypass the need for the putative apocytochrome chaperone CycH during the biogenesis of c-type cytochromes

Author

Karen K. Gabbert, Fevzi Daldal, Meenal Deshmukh, Robert G. Kranz, Matthew May, Katherine A. Karberg, and Yan Zhang

Subjects

Reporter gene, Biochemistry, Operon, Point mutation, Mutant, Consensus sequence, lac operon, Promoter, Biology, Molecular Biology, Microbiology, Biogenesis

Abstract

In Gram-negative bacteria, including Rhodobacter capsulatus, the membrane protein CycH acts as a putative apocytochrome chaperone during the biogenesis of c-type cytochromes. CycH-null mutants are unable to produce various c-type cytochromes and sustain photosynthetic (Ps) growth that requires the cytochromes c1 and c2 or cy. However, Ps+ revertants are readily obtained only on minimal, but not on enriched, medium. To obtain further information about the biogenesis of c-type cytochromes, these suppressor mutants were studied. Complementation of a CycH-null mutant for Ps+ growth by a genomic library constructed using DNA from a Ps+ suppressor yielded a plasmid carrying the ccl1-2 operon, the products of which, Ccl1 and Ccl2, are also involved in the biogenesis of c-type cytochromes. DNA sequence analysis revealed that the complementing activity resulted from a single point mutation, G488A, located upstream of the coding region of ccl1-2. This mutation changed the -35 region of the ccl1-2 promoter from TTGGCC to TTGACC, improving its similarity to the consensus sequence of Escherichia colisigma 70-dependent promoters. That the G488A mutation indeed enhanced transcription of ccl1-2 was demonstrated by the use of reporter gene fusions. An appropriate ccl1-2::lacZ transcriptional-translational fusion carrying the G488A mutation produced in R. capsulatus over 30-fold higher beta-galactosidase activity than a wild-type construct. Immunoblot analyses confirmed that Ccl1 and Ccl2 were overproduced in the Ps+ suppressors. Deletion of either ccl1 or ccl2, from the ccl1-2 cluster carrying the G488A mutation abolished the complementing ability, indicating that overexpression of both ccl1 and ccl2 was required to confer the Ps+ phenotype on a CycH-null mutant. These findings therefore demonstrate that, during R. capsulatus growth on minimal medium, the requirement for CycH in c-type cytochrome biogenesis could be bypassed by overexpressing the ccl1-2 operon.

Published

2002

33. ABC transporters associated with cytochrome c biogenesis

Author

Barry S. Goldman and Robert G. Kranz

Subjects

Hemeproteins, biology, Cytochrome, Cytochrome b, Cytochrome c, Cytochrome c Group, Transporter, ATP-binding cassette transporter, Heme, General Medicine, Microbiology, chemistry.chemical_compound, Bacterial Proteins, Biochemistry, chemistry, biology.protein, ATP-Binding Cassette Transporters, Molecular Biology, Biogenesis, ATP-binding domain of ABC transporters

Abstract

It is generally agreed that cytochrome c biogenesis requires that the apocytochrome and heme be transported separately to their site of function and assembly. In bacteria, this is outside the cytoplasmic membrane, whereby the apocytochromes c use sec-dependent signals for their translocation. Two different hypotheses have recently emerged as to how heme is exported: one involves an helABCD-encoded ATP binding cassette (ABC) transporter complex and the second does not. The second hypothesis concludes that an (HelAB)2 heterodimeric ABC transporter does not transport heme but some other substrate for cytochrome c biogenesis. The evidence supporting each of these two hypotheses and the role of this ABC transporter is discussed.

Published

2001

34. Oxidation−Reduction Properties of Disulfide-Containing Proteins of the Rhodobacter capsulatus Cytochrome c Biogenesis System

Author

Pierre Jacquot, Masakazu Hirasawa, Robert G. Kranz, Barry S. Goldman, Anthony J. Smith, Aaron T. Setterdahl, and David B. Knaff

Subjects

Stereochemistry, Cytochrome c Group, Biochemistry, Rhodobacter capsulatus, chemistry.chemical_compound, Bacterial Proteins, Cysteine, Disulfides, Rhodobacter, biology, Cytochrome c, Titrimetry, Disulfide bond, Membrane Proteins, Dithiol, Oxidation reduction, Hydrogen-Ion Concentration, biology.organism_classification, Recombinant Proteins, chemistry, biology.protein, Cystine, Titration, Oxidation-Reduction, Biogenesis, Bacteria

Abstract

Oxidation-reduction titrations for the active-site disulfide/dithiol couples of the helX- and ccl2-encoded proteins involved in cytochrome c biogenesis in the purple non-sulfur bacterium Rhodobacter capsulatus have been carried out. The R. capsulatus HelX and Ccl2 proteins are predicted to function as part of a dithiol/disulfide cascade that reduces a disulfide on the apocytochromes c so that two cysteine thiols are available to form thioether linkages between the heme prosthetic group and the protein. Oxidation-reduction midpoint potential (E(m)) values, at pH 7.0, of -300 +/- 10 and -210 +/- 10 mV were measured for the HelX and Ccl2 (a soluble, truncated form of Ccl2) R. capsulatus proteins, respectively. Titrations of the disulfide/dithiol couple of a peptide designed to serve as a model for R. capsulatus apocytochrome c(2) have also been carried out, and an E(m) value of -170 +/- 10 mV was measured for the model peptide at pH 7.0. E(m) versus pH plots for HelX, Ccl2, and the apocytochrome c(2) model peptide were all linear over the pH range from 5.0 to 8.0, with the -59 mV/pH unit slope expected for a reaction in which two protons are taken up for each disulfide that is reduced. These results provide thermodynamic support for the proposal that HelX reduces Ccl2 and that reduced Ccl2, in turn, serves as the reductant for the production of the two thiols of the CysXxxYyyCysHis heme-binding motif of the apocytochromes.

Published

2000

35. Translational activation by an NtrC enhancer-binding protein 1 1Edited by K. Yamamoto

Author

Paul J. Cullen, William C. Bowman, Robert G. Kranz, Sean C. Reilly, and Dawn Foster Hartnett

Subjects

Operon, Promoter, biochemical phenomena, metabolism, and nutrition, Biology, Biochemistry, Structural Biology, Transcription (biology), Sigma factor, Enhancer binding, bacteria, rpoN, Pii nitrogen regulatory proteins, Enhancer, Molecular Biology

Abstract

The Rhodobacter capsulatus NtrC protein is a bacterial enhancer-binding protein that activates the transcription of at least five genes by a mechanism that does not require the RpoN RNA polymerase sigma factor. The nifR3-ntrB-ntrC operon in R. capsulatus codes for the nitrogen-sensing two component regulators NtrB and NtrC, as well as for NifR3, a protein of unknown function that is highly conserved in both prokaryotes and eukaryotes. Evidence of a unique translational control of NifR3 mediated directly by the NtrC enhancer-binding protein is reported. The nifR3-ntrB-ntrC operon is expressed from a single promoter upstream of nifR3 with the levels of transcript equivalent in wild-type and ntrC mutants under nitrogen-limited or nitrogen-sufficient conditions. LacZ reporter analyses of this operon and immunological quantitation of NifR3 and NtrC demonstrate that, unlike NtrC levels which remain constant, production of NifR3 is at least ten to 40-fold reduced in NtrC- strains. NifR3 is increased at least fivefold upon nitrogen limitation whereas NtrC production is constitutive. Surprisingly, the purified NtrC protein binds cooperatively to the nifR3 promoter region in vitro at two sets of tandem binding sites centered at +1 and -81 nucleotides relative to the transcriptional start site. Deletion analysis demonstrates that the upstream tandem sites are essential for nitrogen and NtrC-dependent production of NifR3 in vivo , but are not necessary for nifR3 transcription. These experiments indicate that NtrC stimulates the translation of the NifR3 messenger RNA while tethered to the promoter DNA. This is in contrast to five other promoters (nifA1, nifA2, glnB, mopA and anfA) in R. capsulatus which are transcriptionally activated by NtrC bound to one set of tandem binding sites that are centered greater than 100 bp upstream of the transcriptional start site.

Published

1998

36. Transmembrane heme delivery systems

Author

Robert G. Kranz, David L. Beck, Elizabeth M. Monika, and Barry S. Goldman

Subjects

Hemeproteins, Chloroplasts, Hemeprotein, Mitochondrial intermembrane space, Molecular Sequence Data, Protozoan Proteins, ATP-binding cassette transporter, Heme, Biology, Structure-Activity Relationship, chemistry.chemical_compound, Bacterial Proteins, Histidine, Amino Acid Sequence, Integral membrane protein, Plant Proteins, Multidisciplinary, Cytochrome c, Cell Membrane, Tryptophan, Membrane Proteins, Nuclear Proteins, Proteins, Biological Transport, Biological Sciences, Recombinant Proteins, Transmembrane protein, Cell biology, Biochemistry, Membrane protein, chemistry, biology.protein, ATP-Binding Cassette Transporters, Sequence Alignment

Abstract

Heme proteins play pivotal roles in a wealth of biological processes. Despite this, the molecular mechanisms by which heme traverses bilayer membranes for use in biosynthetic reactions are unknown. The biosynthesis of c -type cytochromes requires that heme is transported to the bacterial periplasm or mitochondrial intermembrane space where it is covalently ligated to two reduced cysteinyl residues of the apocytochrome. Results herein suggest that a family of integral membrane proteins in prokaryotes, protozoans, and plants act as transmembrane heme delivery systems for the biogenesis of c -type cytochromes. The complete topology of a representative from each of the three subfamilies was experimentally determined. Key histidinyl residues and a conserved tryptophan-rich region (designated the WWD domain) are positioned at the site of cytochrome c assembly for all three subfamilies. These histidinyl residues were shown to be essential for function in one of the subfamilies, an ABC transporter encoded by helABCD . We believe that a directed heme delivery pathway is vital for the synthesis of cytochromes c , whereby heme iron is protected from oxidation via ligation to histidinyl residues within the delivery proteins.

Published

1998

37. Differential levels of specific cytochrome c biogenesis proteins in response to oxygen: analysis of the ccl operon in Rhodobacter capsulatus

Author

Barry S. Goldman, Karen K. Gabbert, and Robert G. Kranz

Subjects

Transcription, Genetic, Cytochrome, Operon, Molecular Sequence Data, lac operon, Cytochrome c Group, Oxidative phosphorylation, Microbiology, Rhodobacter capsulatus, Bacterial Proteins, Amino Acid Sequence, Promoter Regions, Genetic, Molecular Biology, Sequence Deletion, Rhodobacter, Base Sequence, biology, Cytochrome bc1, Cytochrome c, Gene Expression Regulation, Bacterial, biology.organism_classification, Aerobiosis, Oxygen, Biochemistry, Genes, Bacterial, Mutation, biology.protein, Biogenesis, Research Article

Abstract

The photosynthetic bacterium Rhodobacter capsulatus synthesizes c-type cytochromes under a variety of growth conditions. For example, under aerobic growth, c-type cytochromes are synthesized as part of an electron transport pathway, using oxygen as the terminal electron acceptor. Anaerobically in the light, R. capsulatus requires cytochrome bc1 and other c-type cytochromes for the photosynthetic electron transport pathway. It is shown here that the ccl1 and ccl2 genes of R. capsulatus are required for the synthesis of all c-type cytochromes, including the cytochrome c' protein of unknown function but of structural similarity to cytochrome b562. Polar and nonpolar mutations constructed in each gene demonstrated that the ccl12 genes form an operon. Expression of the ccl12 genes was examined by using lacZ and phoA fusions as translational reporters. Primer extension analysis was used to determine transcriptional control and the start site of the ccl12 promoter. Finally, antiserum to the Ccl2 protein was used to quantitate levels of Ccl2 under six different growth conditions. The Ccl2 protein is present at 20-fold-higher levels under conditions where oxygen is present. In contrast, other cytochromes c biogenesis proteins, HelA and HelX, previously shown to be part of an helABCDX operon, are at relatively similar levels under these six growth conditions. This discovery is discussed in terms of the physiology and evolution of cytochromes c biogenesis, with particular attention to oxidative environments.

Published

1997

38. Interaction of holoCcmE with CcmF in heme trafficking and cytochrome c biosynthesis

Author

Brian San Francisco and Robert G. Kranz

Subjects

Hemeproteins, Cytochrome, Molecular Sequence Data, Heme, Article, chemistry.chemical_compound, Structural Biology, Escherichia coli, Amino Acid Sequence, Molecular Biology, Ternary complex, biology, Cytochrome c, Escherichia coli Proteins, Genetic Complementation Test, Imidazoles, Cytochromes c, Periplasmic space, Protein Transport, chemistry, Biochemistry, Chaperone (protein), biology.protein, Spectrophotometry, Ultraviolet, Holoenzymes, Biogenesis, Bacterial Outer Membrane Proteins, Plasmids

Abstract

The periplasmic heme chaperone holoCcmE is essential for heme trafficking in the cytochrome c biosynthetic pathway in many bacteria, archaea, and plant mitochondria. This pathway, called system I, involves two steps: (i) formation and release of holoCcmE (by the ABC-transporter complex CcmABCD) and (ii) delivery of the heme in holoCcmE to the putative cytochrome c heme lyase complex, CcmFH. CcmFH is believed to facilitate the final covalent attachment of heme (from holoCcmE) to the apocytochrome c. Although most models for system I propose that holoCcmE delivers heme directly to CcmF, no interaction between holoCcmE and CcmF has been demonstrated. Here, a complex between holoCcmE and CcmF is “trapped”, purified, and characterized. HoloCcmE must be released from the ABC-transporter complex CcmABCD to interact with CcmF, and the holo-form of CcmE interacts with CcmF at levels at least 20-fold higher than apoCcmE. Two conserved histidines (here termed P-His1 and P-His2) in separate periplasmic loops in CcmF are required for interaction with holoCcmE, and evidence that P-His1 and P-His2 function as heme-binding ligands is presented. These results show that heme in holoCcmE is essential for complex formation with CcmF and that the heme of holoCcmE is coordinated by P-His1 and P-His2 within the WWD domain of CcmF. These features are strikingly similar to formation of the CcmC:heme:CcmE ternary complex [Richard-Fogal C, Kranz RG. The CcmC:heme:CcmE complex in heme trafficking and cytochrome c biosynthesis. J Mol Biol 2010;401:350–62] and suggest common mechanistic and structural aspects.

Published

2013

39. The temperature-sensitive growth and survival phenotypes of Escherichia coli cydDC and cydAB strains are due to deficiencies in cytochrome bd and are corrected by exogenous catalase and reducing agents

Author

Barry S. Goldman, Robert G. Kranz, and Karen K. Gabbert

Subjects

Cytochrome, Operon, Mutant, medicine.disease_cause, Microbiology, Superoxide dismutase, chemistry.chemical_compound, Escherichia coli, medicine, Molecular Biology, chemistry.chemical_classification, biology, Superoxide Dismutase, Escherichia coli Proteins, Temperature, Gene Expression Regulation, Bacterial, Glutathione, Catalase, Cytochrome b Group, Phenotype, Molecular biology, Enzyme, Electron Transport Chain Complex Proteins, Biochemistry, chemistry, Reducing Agents, biology.protein, Cytochromes, ATP-Binding Cassette Transporters, Oxidoreductases, Research Article

Abstract

The cydDC operon of Escherichia coli encodes an ATP-dependent transporter of unknown function that is required for cytochrome bd synthesis. Strains containing defects in either the cydD or cydC gene also demonstrate hypersensitivity to growth at high temperatures and the inability to exit the stationary phase at 37 degrees C. We wished to determine what is responsible for these hypersensitive phenotypes and whether they are due to a lack of the CydDC proteins or a defect of the cytochrome bd encoded by the cydAB genes. Using both K-12- and B-type strains of E. coli, we have compared the phenotypes of isogenic cydAB mutants and cydC mutants. In both K-12- and B-type backgrounds, the hypersensitive phenotypes are due to defects of cytochrome bd activity and not defects of the cydDC genes. We also found that the temperature-sensitive growth phenotypes can be suppressed by exogenous reducing agents, such as glutathione and cysteine. Strikingly, even the enzymes catalase and superoxide dismutase, when added exogenously, can correct the temperature-sensitive and stationary phase arrest phenotypes. We propose that the temperature sensitive growth phenotypes are due to a buildup of diffusible oxygen radicals brought on by the absence of cytochrome bd.

Published

1996

40. In Vitro Reconstitution and Characterization of the Rhodobacter capsulatus NtrB and NtrC Two-component System

Author

Robert G. Kranz, Paul J. Cullen, and William C. Bowman

Subjects

PII Nitrogen Regulatory Proteins, Recombinant Fusion Proteins, Molecular Sequence Data, Phosphatase, Biochemistry, Rhodobacter capsulatus, chemistry.chemical_compound, Bacterial Proteins, Transcription (biology), RNA polymerase, Escherichia coli, Binding site, Promoter Regions, Genetic, Enhancer, Molecular Biology, Rhodobacter, Base Sequence, biology, Escherichia coli Proteins, Promoter, Cell Biology, biology.organism_classification, DNA-Binding Proteins, Enhancer Elements, Genetic, chemistry, Trans-Activators, bacteria, DNA, Plasmids, Signal Transduction, Transcription Factors

Abstract

Enhancer-dependent transcription in enteric bacteria depends upon an activator protein that binds DNA far upstream from the promoter and an alternative sigma factor (sigma 54) that binds with the core RNA polymerase at the promoter. In the photosynthetic bacterium Rhodobacter capsulatus, the NtrB and NtrC proteins (RcNtrB and RcNtrC) are putative members of a two-component system that is novel because the enhancer-binding RcNtrC protein activates transcription of sigma 54-independent promoters. To reconstitute this putative two-component system in vitro, the ReNtrB protein was overexpressed in Escherichia coli and purified as a maltose-binding protein fusion (MBP-RcNtrB). MBP-RcNtrB autophosphorylates in vitro to the same steady state level and with the same stability as the Salmonella typhimurium NtrB (StNtrB) protein but at a lower initial rate. MBP-RcNtrB autophosphorylates the S.typhimurium NtrC (St-NtrC) and RcNtrC proteins in vitro. The enteric NtrC protein is also phosphorylated in vivo by RcNtrB because plasmids that encode either RcNtrB or MBP-Rc-NtrB activate transcription of an NtrC-dependent nifL-lacZ fusion. The rate of phosphotransfer to RcNtrC and autophosphatase activity of phosphorylated RcNtrC (RcNtrC---P) are comparable to the StNtrC protein. However, the RcNtrC protein appears to be a specific RcNtrB P phosphatase since RcNtrC is not phosphorylated by small molecular weight phosphate compounds or by the StNtrB protein. RcNtrC forms a dimer in solution, and RcNtrC - P binds the upstream tandem binding sites of the g1nB promoter 4-fold better than the unphos-phorylated RcNtrC protein, presumably due to oligomerization of RcNtrC -P. Therefore, the R. capsulatus NtrB and NtrC proteins form a two-component system similar to other NtrC-like systems, where specific Rc- NtrB phosphotransfer to the RcNtrC protein results in increased oligoinerization at the enhancer but with subsequent activation of a sigma 54-independent promoter.

Published

1996

41. Human mitochondrial holocytochrome c synthase's heme binding, maturation determinants, and complex formation with cytochrome c

Author

Eric C. Bretsnyder, Robert G. Kranz, and Brian San Francisco

Subjects

Models, Molecular, Heme binding, Cytochrome, Molecular Sequence Data, Lyases, Plasma protein binding, Heme, Ligands, Cofactor, Rhodobacter capsulatus, chemistry.chemical_compound, Bacterial Proteins, Humans, Histidine, Amino Acid Sequence, neoplasms, Multidisciplinary, biology, Cytochrome c, Cytochromes c, HCCS, digestive system diseases, Mitochondria, chemistry, Biochemistry, PNAS Plus, biology.protein, Spectrophotometry, Ultraviolet, Protein Binding

Abstract

Proper functioning of the mitochondrion requires the orchestrated assembly of respiratory complexes with their cofactors. Cytochrome c , an essential electron carrier in mitochondria and a critical component of the apoptotic pathway, contains a heme cofactor covalently attached to the protein at a conserved CXXCH motif. Although it has been known for more than two decades that heme attachment requires the mitochondrial protein holocytochrome c synthase (HCCS), the mechanism remained unknown. We purified membrane-bound human HCCS with endogenous heme and in complex with its cognate human apocytochrome c . Spectroscopic analyses of HCCS alone and complexes of HCCS with site-directed variants of cytochrome c revealed the fundamental steps of heme attachment and maturation. A conserved histidine in HCCS (His154) provided the key ligand to the heme iron. Formation of the HCCS:heme complex served as the platform for interaction with apocytochrome c . Heme was the central molecule mediating contact between HCCS and apocytochrome c . A conserved histidine in apocytochrome c (His19 of CXXCH) supplied the second axial ligand to heme in the trapped HCCS:heme:cytochrome c complex. We also examined the substrate specificity of human HCCS and converted a bacterial cytochrome c into a robust substrate for the HCCS. The results allow us to describe the molecular mechanisms underlying the HCCS reaction.

Published

2012

42. The Rhodobacter capsulatus glnB gene is regulated by NtrC at tandem rpoN-independent promoters

Author

D. Foster-Hartnett and Robert G. Kranz

Subjects

Transcription, Genetic, PII Nitrogen Regulatory Proteins, Molecular Sequence Data, lac operon, Sigma Factor, Biology, environment and public health, Microbiology, Rhodobacter capsulatus, Primer extension, Bacterial Proteins, Transcription (biology), Nitrogen Fixation, Genes, Regulator, Gene expression, RNA, Messenger, Promoter Regions, Genetic, Molecular Biology, Gene, DNA Primers, Genetics, Binding Sites, Rhodobacter, Base Sequence, Promoter, DNA-Directed RNA Polymerases, Gene Expression Regulation, Bacterial, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Cell biology, DNA-Binding Proteins, Genes, Bacterial, Trans-Activators, bacteria, rpoN, RNA Polymerase Sigma 54, Transcription Factors, Research Article

Abstract

The protein encoded by glnB of Rhodobacter capsulatus is part of a nitrogen-sensing cascade which regulates the expression of nitrogen fixation genes (nif). The expression of glnB was studied by using lacZ fusions, primer extension analysis, and in vitro DNase I footprinting. Our results suggest that glnB is transcribed from two promoters, one of which requires the R. capsulatus ntrC gene but is rpoN independent. Another promoter upstream of glnB is repressed by NtrC; purified R. capsulatus NtrC binds to sites that overlap this distal promoter region.

Published

1994

43. Structure and expression of the alternative sigma factor, RpoN, in Rhodobacter capsulatus; physiological relevance of an autoactivated nifU2-rpoN superoperon

Author

Robert G. Kranz, Karen K. Gabbert, D. Foster-Hartnett, and Paul J. Cullen

Subjects

Operon, Recombinant Fusion Proteins, Molecular Sequence Data, Sigma Factor, Microbiology, Rhodobacter capsulatus, Insertional mutagenesis, Bacterial Proteins, Ammonia, Sigma factor, Nitrogen Fixation, Amino Acid Sequence, Cloning, Molecular, Promoter Regions, Genetic, Molecular Biology, Gene, Alleles, Genetics, Rhodobacter, Base Sequence, biology, Chromosome Mapping, Promoter, DNA-Directed RNA Polymerases, Gene Expression Regulation, Bacterial, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, DNA-Binding Proteins, Mutagenesis, Insertional, Open reading frame, Genes, Bacterial, bacteria, rpoN, RNA Polymerase Sigma 54, Sequence Alignment, Sequence Analysis

Abstract

The alternative sigma factor, RpoN (sigma 54) is responsible for recruiting core RNA polymerase to the promoters of genes required for diverse physiological functions in a variety of eubacterial species. The RpoN protein in Rhodobacter capsulatus is a putative sigma factor specific for nitrogen fixation (nif) genes. Insertional mutagenesis was used to define regions important for the function of the R. capsulatus RpoN protein. Insertions of four amino acids in the predicted helixturn-helix or in the highly conserved C-terminal eight amino acid residues (previously termed the RpoN box), and an in-frame deletion of the glutamine-rich N-terminus completely inactivated the R. capsulatus RpoN protein. Two separate insertions in the second hydrophobic heptad repeat, a putative leucine zipper, resulted in a partially functional RpoN protein. Eight other linkers in the rpoN open reading frame (ORF) resulted in a completely or partially functional RpoN protein. The rpoN gene in R. capsulatus is downstream from the nifHDKU2 genes, in a nifU2-rpoN operon. Results of genetic experiments on the nifU2-rpoN locus show that the rpoN gene is organized in a nifU2-rpoN superoperon. A primary promoter directly upstream of the rpoN ORF is responsible for the initial expression of rpoN. Deletion analysis and insertional mutagenesis were used to define the primary promoter to 50 bp, between 37 and 87 nucleotides upstream of the predicted rpoN translational start site. This primary promoter is expressed constitutively with respect to nitrogen, and it is necessary and sufficient for growth under nitrogen-limiting conditions typically used in the laboratory. A secondary promoter upstream of nifU2 is autoactivated by RpoN and NifA to increase the expression of rpoN, which ultimately results in higher expression of RpoN-dependent genes. Moreover, rpoN expression from this secondary promoter is physiologically beneficial under certain stressful conditions, such as nitrogen-limiting environments that contain high salt (> 50 mM NaCl) or low iron (< 400 nM FeSO4).

Published

1994

44. The CcmC:Heme:CcmE Complex in Heme Trafficking and Cytochrome c Biosynthesis

Author

Cynthia L. Richard-Fogal and Robert G. Kranz

Subjects

Hemeproteins, Heme binding, Cytochrome, Stereochemistry, Plasma protein binding, Heme, Article, chemistry.chemical_compound, Bacterial Proteins, Structural Biology, Binding site, Molecular Biology, Integral membrane protein, Binding Sites, biology, Escherichia coli Proteins, Cytochromes c, Membrane Proteins, Biological Transport, Transport protein, Protein Transport, chemistry, Biochemistry, Amino Acid Substitution, Multiprotein Complexes, biology.protein, Bacterial Outer Membrane Proteins, Protein Binding

Abstract

A superfamily of integral membrane proteins is characterized by a conserved tryptophan-rich region (called the WWD domain) in an external loop at the inner membrane surface. The three major members of this family (CcmC, CcmF, and CcsBA) are each involved in cytochrome c biosynthesis, yet the function of the WWD domain is unknown. It has been hypothesized that the WWD domain binds heme to present it to an acceptor protein (apoCcmE for CcmC or apocytochrome c for CcmF and CcsBA) such that the heme vinyl group(s) covalently attaches to the acceptors. Alternative proposals suggest that the WWD domain interacts directly with the acceptor protein (e.g., apoCcmE for CcmC). Here, it is shown that CcmC is only trapped with heme when its cognate acceptor protein CcmE is present. It is demonstrated that CcmE only interacts stably with CcmC when heme is present; thus, specific residues in each protein provide sites of interaction with heme to form this very stable complex. For the first time, evidence that the external WWD domain of CcmC interacts directly with heme is presented. Single and multiple substitutions of completely conserved residues in the WWD domain of CcmC alter the spectral properties of heme in the stable CcmC:heme:CcmE complexes. Moreover, some mutations reduce the binding of heme up to 100%. It is likely that endogenously synthesized heme enters the external WWD domain of CcmC either via a channel within this six-transmembrane-spanning protein or from the membrane. The data suggest that a specific heme channel (i.e., heme binding site within membrane spanning helices) is not present in CcmC, in contrast to the CcsBA protein. We discuss the likelihood that it is not important to protect the heme via trafficking in CcmC whereas it is critical in CcsBA.

Published

2010

45. DNA gyrase activities fromRhodobacter capsulatus: analysis of target(s) of coumarins and cloning of thegyrBlocus

Author

Robert G. Kranz, Diana L. Beckman, and Dawn Foster-Hartnett

Subjects

Genetics, Molecular Biology, Microbiology

Published

1992

46. Analysis of the promoters and upstream sequences of nifA1 aud nifA2 in Rhodobacter capsulatus; activation requires ntrC but not rpoN

Author

Robert G. Kranz and D. Foster-Hartnett

Subjects

DNA, Bacterial, Nitrogen, Molecular Sequence Data, lac operon, Sigma Factor, Microbiology, Rhodobacter capsulatus, Primer extension, chemistry.chemical_compound, Transcription (biology), Sigma factor, Nitrogen Fixation, RNA polymerase, Cloning, Molecular, Promoter Regions, Genetic, Molecular Biology, Genetics, Rhizobium leguminosarum, Rhodobacter, Base Sequence, biology, Promoter, DNA-Directed RNA Polymerases, Gene Expression Regulation, Bacterial, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, DNA-Binding Proteins, Oxygen, RNA, Bacterial, Lac Operon, chemistry, Genes, Bacterial, bacteria, rpoN, Chromosome Deletion, RNA Polymerase Sigma 54, Plasmids

Abstract

Transcription of Rhodobacter capsulatus genes encoding the nitrogenase polypeptides (nifHDK) is repressed by fixed nitrogen and oxygen. R. capsulatus nifA1 and nifA2 encode identical NIFA proteins that activate transcription of nifHDK and other nif genes. In this study, we report that nifA1-lacZ and nifA2-lacZ fusions are repressed in the presence of NH3 and activated to similar levels under nitrogen-deficient conditions. This nitrogen-controlled activation was dependent on R. capsulatus ntrC (which encodes a transcriptional activator) but not rpoN (which encodes an RNA polymerase sigma factor). We have used primer extension analyses of nifA1, nifA2 and nifH and deletion analyses of nifA1 and nifA2 upstream regions to define likely promoters and cis upstream activation sequences required for nitrogen control of these genes. Primer extension mapping confirmed that ntrC but not rpoN is required for nifA1 and nifA2 activation, and that nifA1 and nifA2 do not possess typical RPON-activated promoters.

Published

1992

47. CcsBA is a cytochrome c synthetase that also functions in heme transport

Author

Elaine R. Frawley and Robert G. Kranz

Subjects

Chloroplasts, Hemeprotein, Heme binding, Lyases, Heme, Biology, Ligands, Catalysis, chemistry.chemical_compound, Escherichia coli, Histidine, Amino Acid Sequence, Integral membrane protein, Conserved Sequence, Phylogeny, chemistry.chemical_classification, Multidisciplinary, Bacteria, Cell Membrane, Core Binding Factors, Imidazoles, Cytochromes c, Cytochrome P450 reductase, Membrane Proteins, Biological Transport, Biological Sciences, Heme transport, Conjugated protein, Recombinant Proteins, Protein Structure, Tertiary, Transmembrane domain, chemistry, Biochemistry, Mutation, Commentary

Abstract

Little is known about trafficking of heme from its sites of synthesis to sites of heme-protein assembly. We describe an integral membrane protein that allows trapping of endogenous heme to elucidate trafficking mechanisms. We show that CcsBA, a representative of a superfamily of integral membrane proteins involved in cytochrome c biosynthesis, exports and protects heme from oxidation. CcsBA has 10 transmembrane domains (TMDs) and reconstitutes cytochrome c synthesis in the Escherichia coli periplasm; thus, CcsBA is a cytochrome c synthetase. Purified CcsBA contains heme in an “external heme binding domain” for which two external histidines are shown to serve as axial ligands that protect the heme iron from oxidation. This is likely the active site of the synthetase. Furthermore, two conserved histidines in TMDs are required for heme to travel to the external heme binding domain. Remarkably, the function of CcsBA with mutations in these TMD histidines is corrected by exogenous imidazole, a result analogous to correction of heme binding by myoglobin when its proximal histidine is mutated. These data suggest that CcsBA has a heme binding site within the bilayer and that CcsBA is a heme channel.

Published

2009

48. Biogenesis of c-type Cytochromes and Cytochrome Complexes

Author

Fevzi Daldal, Özlem Önder, Robert G. Kranz, Elaine R. Frawley, Hans-Georg Koch, Carsten Sanders, and Serdar Turkarslan

Subjects

chemistry.chemical_classification, biology, Cytochrome, Chemistry, Cytochrome b, Cytochrome c, Periplasmic space, Anoxygenic photosynthesis, chemistry.chemical_compound, Biochemistry, Oxidoreductase, biology.protein, Heme, Biogenesis

Abstract

In most anoxygenic phototrophic bacteria, apocytochromes c are synthesized in the cytoplasm, translocated across the membrane and matured to holocytochromes c on the periplasmic side. The extracytoplasmic maturation process requires a complex biogenesis pathway (Ccm-system I) consisting of up to ten components to carry out specific steps. These include translocation and delivery of the heme, chaperoning and thio-oxidoreduction of the apocytochrome c as well as heme ligation steps. Because cytochromes are often part of multi-subunit protein complexes, matured holocytochromes may be assembled into active enzyme complexes. Examples include the ubihydroquinone:cytochrome c oxidoreductase (cytochrome bc 1 complex) or the aa 3- or cbb 3-type cytochrome c oxidases. Assemblies of these complexes are tightly coordinated and often require additional specific biogenesis components. In this chapter, we discuss the maturation process of c-type cytochromes and the assembly pathways of the aa 3- and cbb 3-type cytochrome c oxidases in anoxygenic phototrophic bacteria, with a specific focus on Rhodobacter species.

Published

2009

49. Topology and function of CcmD in cytochrome c maturation

Author

Elaine R. Frawley, Robert G. Kranz, and Cynthia L. Richard-Fogal

Subjects

Topology, Microbiology, Cell membrane, chemistry.chemical_compound, Bacterial Proteins, medicine, Escherichia coli, Molecular Biology, Heme, biology, Cytochrome c, C-terminus, Escherichia coli Proteins, Cell Membrane, Cytochromes c, Membrane Proteins, Biological Transport, Periplasmic space, Enzymes and Proteins, Transmembrane domain, medicine.anatomical_structure, chemistry, Membrane protein, Genes, Bacterial, biology.protein, ATP-Binding Cassette Transporters, Biogenesis

Abstract

The system I cytochrome c biogenesis pathway requires CcmD, a small polypeptide of 69 residues in Escherichia coli . Here it is shown that CcmD is a component of the CcmABC ATP-binding cassette transporter complex. CcmD is not necessary for the CcmC-dependent transfer of heme to CcmE in the periplasm or for interaction of CcmE with CcmABC. CcmD is absolutely required for the release of holo-CcmE from the CcmABCD complex. Evidence is presented that the topology of CcmD in the cytoplasmic membrane is the N terminus outside and the C terminus inside with one transmembrane domain.

Published

2008

50. Inactivation, sequence, and lacZ fusion analysis of a regulatory locus required for repression of nitrogen fixation genes in Rhodobacter capsulatus

Author

V M Pace, Robert G. Kranz, and I M Caldicott

Subjects

DNA, Bacterial, Transcription, Genetic, Operon, Molecular Sequence Data, Mutant, lac operon, Locus (genetics), Microbiology, Transcription (biology), Nitrogen Fixation, Sequence Homology, Nucleic Acid, Genes, Regulator, Escherichia coli, Molecular Biology, Gene, Psychological repression, Rhodobacter, Base Sequence, biology, biology.organism_classification, Rhodospirillaceae, Lac Operon, Biochemistry, Genes, Bacterial, DNA Transposable Elements, bacteria, Research Article

Abstract

Transcription of the genes that code for proteins involved in nitrogen fixation in free-living diazotrophs is typically repressed by high internal oxygen concentrations or exogenous fixed nitrogen. The DNA sequence of a regulatory locus required for repression of Rhodobacter capsulatus nitrogen fixation genes was determined. It was shown that this locus, defined by Tn5 insertions and by ethyl methanesulfonate-derived mutations, is homologous to the glnB gene of other organisms. The R. capsulatus glnB gene was upstream of glnA, the gene for glutamine synthetase, in a glnBA operon. beta-Galactosidase expression from an R. capsulatus glnBA-lacZ translational fusion was increased twofold in cells induced by nitrogen limitation relative to that in cells under nitrogen-sufficient conditions. R. capsulatus nifR1, a gene that was previously shown to be homologous to ntrC and that is required for transcription of nitrogen fixation genes, was responsible for approximately 50% of the transcriptional activation of this glnBA fusion in cells induced under nitrogen-limiting conditions. R. capsulatus GLNB, NIFR1, and NIFR2 (a protein homologous to NTRB) were proposed to transduce the nitrogen status in the cell into repression or activation of other R. capsulatus nif genes. Repression of nif genes in response to oxygen was still present in R. capsulatus glnB mutants and must have occurred at a different level of control in the regulatory circuit.

Published

1990