Structural and Biochemical Studies of the Metal Binding Protein CusF and its Role in Escherichia coli Copper Homeostasis

Loftin, Isabell

January 2008

Biometals such as copper, cobalt and zinc are essential to life. These transition metals are used as cofactors in many enzymes. Nonetheless, these metals cause deleterious effects if their intracellular concentration exceeds the cells' requirement. Prokaryotic organisms usually employ efflux systems to maintain metals in appropriate intracellular concentrations.The Cus system of Escherichia coli plays a crucial part in the copper homeostasis of the organism. This system is a tetrapartite efflux system, which includes an additional component compared to similar efflux systems. This fourth component is a small periplasmic protein, CusF. CusF is essential for full copper resistance, yet its role within the Cus system has not been characterized. It could potentially serve in the role of a metallochaperone or as a regulator to the Cus system.To gain insight into the molecular mechanism of resistance of this system, I have structurally and biochemically characterized CusF. Using X-ray crystallography I determined the CusF structure. CusF displays a novel fold for a copper binding protein. Through multiple sequence alignment and NMR chemical shift experiments, I proposed a metal binding site in CusF, which I confirmed through determination of the structure of CusF-Ag(I). CusF displays a novel coordination of Ag(I) and Cu(I) through a Met2His motif and a cation-pi interaction between the metal ion and a tryptophan sidechain. Furthermore, I have shown that CusF binds Cu(I) and Ag(I) specifically and tightly.I investigated the role of the tryptophan at the binding site to establish its effect on metal binding and function of CusF. I have shown through competitive binding assays, NMR studies and through collaborative EXAFS studies that the tryptophan plays an essential role in CusF metal handling. The affinity of CusF for Cu(I) is influenced by this residue. Moreover, the tryptophan also caps the binding site such that oxidation of the bound metal as well access to adventitious ligands is prevented. In summary, these findings show that the structure and metal site of CusF are unique and are specifically designed to perform the function of CusF as a metallochaperone to the Cus system.

copper

metallochaperone

periplasmic protein

copper chaperone

copper homeostasis

protein structure

Spectroscopic studies of the human copper chaperone for superoxide dismutase : probing the active cluster with selenocysteine variants

Barry, Amanda Nell

10 1900

Ph.D. / Biochemistry and Molecular Biology / Selenocysteine-containing mutants of human copper chaperone for superoxide dismutase (hCCS) were constructed using intein-mediated peptide ligation. These mutants were studied with respect to their ability to transfer Cu to E,Zn superoxide dismutase (SOD1) and their Cu-binding and X-ray absorption spectroscopic (XAS) properties. Previous studies have shown that three functionally distinct polypeptide domains are present in CCS: the N-terminal domain 1 (D1, residues 1-85) contains the copper-binding MXCXXC motif, domain 2 (D2, residues 86-234) has sequence homology to residues associated with the native SOD1 dimer interface, and the C-terminal domain 3 (D3, residues 235-274) contains a CXC motif. Recent results suggest the formation of a D3- D3 cluster within a dimeric or tetrameric protein and suggest that this cluster may be an important element of the copper transfer machinery. D3 cysteine-to-selenocysteine mutants of wild-type and D1 mutants of hCCS were constructed to investigate the D3 copper cluster in more detail. These mutants display similar activity to wild-type protein. The structure of the Cu centers of selenocysteine-containing mutants as shown by Cu EXAFS is similar to that of wild-type protein, with clear indications of a Cu cluster. Cu and Se EXAFS of these constructs reveal a unique adamantane-like cluster formed between two molecules of CCS at the D3-D3 interface. These results confirm the existence of a D3-D3 copper cluster in hCCS and suggest that a unique copper cluster may exist in this protein.

Human copper ion transfer : from metal chaperone to target transporter domain

Niemiec, Moritz Sebastian

January 2015

Many processes in living systems occur through transient interactions among proteins. Those interactions are often weak and are driven by small changes in free energy. Due to the short-living nature of these interactions, our knowledge about driving forces, dynamics and structures of these types of protein-protein heterocomplexes are though limited. This is especially important for cellular copper (Cu) trafficking: Copper ions are essential for all eukaryotes and most bacteria. As a cofactor in many enzymes, copper is especially vital in respiration or detoxification. Since the same features that make copper useful also make it toxic, it needs to be controlled tightly. Additionally, in the reducing environment of the cytosol, Cu is present as insoluble Cu(I). To circumvent both toxicity and solubility issues, a system has evolved where copper is comforted by certain copper binding proteins, so-called Cu-chaperones. They transiently interact with each other to distribute the Cu atoms in a cell. In humans, one of them is Atox1. It binds copper with a binding site containing two thiol residues and transfers it to other binding sites, mostly those of a copper pump, ATP7B (also known as Wilsons disease protein). My work was aimed at understanding copper-mediated protein-protein interactions on a molecular and mechanistic level. Which amino acids interact with the metal? Which forces drive the transfer from one protein to the other? Using biophysical and biochemical methods such as chromatography and calorimetry on wild type and point-mutated proteins in vitro, we found that the copper is transferred via a dynamic intermediate complex that keeps the system flexible while shielding the copper against other interactions. Although similar transfer interactions can be observed in other organisms, and many conclusions in the copper field are drawn from bacterial and yeast analogs, we believe that it is important to investigate human proteins, too. Not only is their regulation different, but also only in humans we find the diseases linked to the proteins: Copper level regulation diseases are to be named first, but atypical copper levels have also been linked to tumors and amyloid dispositions. In summary, my observations and conclusions are of basic research character and can be of importance for both general copper and human medicinal research.

copper homeostasis

copper chaperone

Atox1

ATP7B

Wilson disease protein

metal transport

size exclusion chromatography

thermodynamics

isothermal calorimetry

Expressão heteróloga e caracterização funcional da proteína Atx1 em Paracoccidioides spp / Heterologous expression and functional characterization of Atx1 protein in Paracoccidioides spp

Morais, Camila Oliveira Barbosa de

13 April 2018

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Expressão heteróloga

Proteína Atx1

Chaperona de cobre

Micronutriente

Privação de cobre

Heterologous expression

Atx1 proteín

Copper chaperone

Micronutriente

Copper deprivation

CIENCIAS BIOLOGICAS::MICROBIOLOGIA

Divergent functions of the Arabidopsis mitochondrial SCO proteins: HCC1 is essential for COX activity while HCC2 is involved in the UV-B stress response

Steinebrunner, Iris, Gey, Uta, Andres, Manuela, Garcia, Lucila, Gonzalez, Daniel H.

11 July 2014

The two related putative cytochrome c oxidase (COX) assembly factors HCC1 and HCC2 from Arabidopsis thaliana are Homologs of the yeast Copper Chaperones Sco1p and Sco2p. The hcc1 null mutation was previously shown to be embryo lethal while the disruption of the HCC2 gene function had no obvious effect on plant development, but increased the expression of stress-responsive genes. Both HCC1 and HCC2 contain a thioredoxin domain, but only HCC1 carries a Cu-binding motif also found in Sco1p and Sco2p. In order to investigate the physiological implications suggested by this difference, various hcc1 and hcc2 mutants were generated and analyzed. The lethality of the hcc1 knockout mutation was rescued by complementation with the HCC1 gene under the control of the embryo-specific promoter ABSCISIC ACID INSENSITIVE 3. However, the complemented seedlings did not grow into mature plants, underscoring the general importance of HCC1 for plant growth. The HCC2 homolog was shown to localize to mitochondria like HCC1, yet the function of HCC2 is evidently different, because two hcc2 knockout lines developed normally and exhibited only mild growth suppression compared with the wild type (WT). However, hcc2 knockouts were more sensitive to UV-B treatment than the WT. Complementation of the hcc2 knockout with HCC2 rescued the UV-B-sensitive phenotype. In agreement with this, exposure of wild-type plants to UV-B led to an increase of HCC2 transcripts. In order to corroborate a function of HCC1 and HCC2 in COX biogenesis, COX activity of hcc1 and hcc2 mutants was compared. While the loss of HCC2 function had no significant effect on COX activity, the disruption of one HCC1 gene copy was enough to suppress respiration by more than half compared with the WT. Therefore, we conclude that HCC1 is essential for COX function, most likely by delivering Cu to the catalytic center. HCC2, on the other hand, seems to be involved directly or indirectly in UV-B-stress responses.

SCO

Synthese

Cytochrom-c-Oxidase

Mitochondrien

Kupferchaperon

COX-Komplex

UV-B

Stress

Pflanzenwachstum

Pflanzenentwicklung

BN-PAGE

Arabidopsis thaliana

TU Dresden

Publikationsfonds

SCO (synthesis of cytochrome c oxidase)

mitochondria

copper chaperone

COX complex

UV-B stress

plant growth and development

BN-PAGE

Arabidopsis thaliana

Technical University Dresden

Publication funds

ddc:570

rvk:WA 15000

Divergent functions of the Arabidopsis mitochondrial SCO proteins: HCC1 is essential for COX activity while HCC2 is involved in the UV-B stress response

Steinebrunner, Iris, Gey, Uta, Andres, Manuela, Garcia, Lucila, Gonzalez, Daniel H.

11 July 2014

The two related putative cytochrome c oxidase (COX) assembly factors HCC1 and HCC2 from Arabidopsis thaliana are Homologs of the yeast Copper Chaperones Sco1p and Sco2p. The hcc1 null mutation was previously shown to be embryo lethal while the disruption of the HCC2 gene function had no obvious effect on plant development, but increased the expression of stress-responsive genes. Both HCC1 and HCC2 contain a thioredoxin domain, but only HCC1 carries a Cu-binding motif also found in Sco1p and Sco2p. In order to investigate the physiological implications suggested by this difference, various hcc1 and hcc2 mutants were generated and analyzed. The lethality of the hcc1 knockout mutation was rescued by complementation with the HCC1 gene under the control of the embryo-specific promoter ABSCISIC ACID INSENSITIVE 3. However, the complemented seedlings did not grow into mature plants, underscoring the general importance of HCC1 for plant growth. The HCC2 homolog was shown to localize to mitochondria like HCC1, yet the function of HCC2 is evidently different, because two hcc2 knockout lines developed normally and exhibited only mild growth suppression compared with the wild type (WT). However, hcc2 knockouts were more sensitive to UV-B treatment than the WT. Complementation of the hcc2 knockout with HCC2 rescued the UV-B-sensitive phenotype. In agreement with this, exposure of wild-type plants to UV-B led to an increase of HCC2 transcripts. In order to corroborate a function of HCC1 and HCC2 in COX biogenesis, COX activity of hcc1 and hcc2 mutants was compared. While the loss of HCC2 function had no significant effect on COX activity, the disruption of one HCC1 gene copy was enough to suppress respiration by more than half compared with the WT. Therefore, we conclude that HCC1 is essential for COX function, most likely by delivering Cu to the catalytic center. HCC2, on the other hand, seems to be involved directly or indirectly in UV-B-stress responses.

info:eu-repo/classification/ddc/570

ddc:570