Francesca Cantini scite author profile

Cellular systems allow transition-metal ions to reach or leave the cell or intracellular locations through metal transfer between proteins. By coupling mutagenesis and advanced NMR experiments, we structurally characterized the adduct between the copper chaperone Atx1 and the first copper(I)-binding domain of the Ccc2 ATPase. Copper was required for the interaction. This study provides an understanding of metal-mediated protein-protein interactions in which the metal ion is essential for the weak, reversible interaction between the partners.

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Characterization of the Binding Interface between the Copper Chaperone Atx1 and the First Cytosolic Domain of Ccc2 ATPase

Arnesano¹,

Banci²,

Bertini³

et al. 2001

Journal of Biological Chemistry

144

166

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Solution Structure of the Apo and Copper(I)-Loaded Human Metallochaperone HAH1

et al. 2004

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The human metallochaperone HAH1 has been produced in Escherichia coli with four additional amino acids at the C-terminus and characterized in solution by NMR spectroscopy, both with and without copper(I). The solution structure of the apo-HAH1 monomer has a root-mean-square-deviation (RMSD) of 0.50 A for the coordinates of the backbone atoms and 0.96 A for all heavy atoms. These values compare, respectively, with 0.45 and 0.95 A for copper(I)-HAH1. There are only minor structural rearrangements upon copper(I) binding. In particular, the variation of interatomic interactions around the metal-binding region is limited to a movement of Lys60 toward the metal site. The protein structures are similar to those obtained by X-ray crystallography in a variety of derivatives, with backbone RMSD values below 1 A. In the holoprotein, copper(I) is confirmed to be two coordinated. If these data are compared with those of orthologue proteins, we learn that HAH1 has a lower tendency to change coordination number from two to three. Such a switch in coordination is a key step in copper transfer.

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Structural basis for the mutual antagonism of cAMP and TRIP8b in regulating HCN channel function

Saponaro

Pauleta

Cantini

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

134

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cAMP signaling in the brain mediates several higher order neural processes. Hyperpolarization-activated cyclic nucleotide-gated (HCN) channels directly bind cAMP through their cytoplasmic cyclic nucleotide binding domain (CNBD), thus playing a unique role in brain function. Neuronal HCN channels are also regulated by tetratricopeptide repeat-containing Rab8b interacting protein (TRIP8b), an auxiliary subunit that antagonizes the effects of cAMP by interacting with the channel CNBD. To unravel the molecular mechanisms underlying the dual regulation of HCN channel activity by cAMP/ TRIP8b, we determined the NMR solution structure of the HCN2 channel CNBD in the cAMP-free form and mapped on it the TRIP8b interaction site. We reconstruct here the full conformational changes induced by cAMP binding to the HCN channel CNBD. Our results show that TRIP8b does not compete with cAMP for the same binding region; rather, it exerts its inhibitory action through an allosteric mechanism, preventing the cAMP-induced conformational changes in the HCN channel CNBD.

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Human superoxide dismutase 1 (hSOD1) maturation through interaction with human copper chaperone for SOD1 (hCCS)

Banci

Bertini

Cantini

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

124

144

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Copper chaperone for superoxide dismutase 1 (SOD1), CCS, is the physiological partner for the complex mechanism of SOD1 maturation. We report an in vitro model for human CCS-dependent SOD1 maturation based on the study of the interactions of human SOD1 (hSOD1) with full-length WT human CCS (hCCS), as well as with hCCS mutants and various truncated constructs comprising one or two of the protein’s three domains. The synergy between electrospray ionization mass spectrometry (ESI-MS) and NMR is fully exploited. This is an in vitro study of this process at the molecular level. Domain 1 of hCCS is necessary to load hSOD1 with Cu(I), requiring the heterodimeric complex formation with hSOD1 fostered by the interaction with domain 2. Domain 3 is responsible for the catalytic formation of the hSOD1 Cys-57–Cys-146 disulfide bond, which involves both hCCS Cys-244 and Cys-246 via disulfide transfer.

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In-cell NMR reveals potential precursor of toxic species from SOD1 fALS mutants

et al. 2014

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Mutations in the superoxide dismutase 1 (SOD1) gene are related to familial cases of amyotrophic lateral sclerosis (fALS). Here we exploit in-cell NMR to characterize the protein folding and maturation of a series of fALS-linked SOD1 mutants in human cells and to obtain insight into their behaviour in the cellular context, at the molecular level. The effect of various mutations on SOD1 maturation are investigated by changing the availability of metal ions in the cells, and by coexpressing the copper chaperone for SOD1, hCCS. We observe for most of the mutants the occurrence of an unstructured SOD1 species, unable to bind zinc. This species may be a common precursor of potentially toxic oligomeric species, that are associated with fALS. Coexpression of hCCS in the presence of copper restores the correct maturation of the SOD1 mutants and prevents the formation of the unstructured species, confirming that hCCS also acts as a molecular chaperone.

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Structural and dynamic aspects related to oligomerization of apo SOD1 and its mutants

Banci

Bertini²,

Boca³

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

112

132

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The structural and dynamical properties of the metal-free form of WT human superoxide dismutase 1 (SOD1) and its familial amyotrophic lateral sclerosis (fALS)-related mutants, T54R and I113T, were characterized both in solution, through NMR, and in the crystal, through X-ray diffraction. We found that all 3 X-ray structures show significant structural disorder in 2 loop regions that are, at variance, well defined in the fully-metalated structures. Interestingly, the apo state crystallizes only at low temperatures, whereas all 3 proteins in the metalated form crystallize at any temperature, suggesting that crystallization selects one of the most stable conformations among the manifold adopted by the apo form in solution. Indeed, NMR experiments show that the protein in solution is highly disordered, sampling a large range of conformations. The large conformational variability of the apo state allows the free reduced cysteine Cys-6 to become highly solvent accessible in solution, whereas it is essentially buried in the metalated state and the crystal structures. Such solvent accessibility, together with that of Cys-111, accounts for the tendency to oligomerization of the metal-free state. The present results suggest that the investigation of the solution state coupled with that of the crystal state can provide major insights into SOD1 pathway toward oligomerization in relation to fALS.amyotrophic lateral sclerosis ͉ NMR ͉ X-ray ͉ mobility ͉ H2O/D2O exchange M ore than 100 different variants of human copper-zinc superoxide dismutase (Cu 2 Zn 2 SOD) have been identified and linked to the neurodegenerative disease familial amyotrophic lateral sclerosis (fALS) by a gain-of-function mechanism (1, 2). Although the mechanism of the toxicity is unknown, aberrant SOD1 protein oligomerization has been strongly implicated in disease causation (3,4). Several recent publications (5, 6) have presented compelling evidence that in vivo abnormal disulfide cross-linking of ALS mutant SOD1 plays a role in this oligomerization, and disulfide-linked SOD1 multimers have been detected mainly in mitochondria of neuronal tissues of SOD1-linked fALS patients and transgenic mice (7-9).WT human SOD1 is an exceptionally stable, homodimeric 32-kDa protein, located mainly in the cytoplasm, but it is also present in the peroxisomes, the mitochondrial intermembrane space, and the nucleus of eukaryotic cells (10, 11). Each subunit of the dimer binds 1 copper and 1 zinc ion and folds as an 8-stranded Greek-key ␤-barrel that is stabilized by an intrasubunit disulfide bond (Cys-57, Cys-146) near the active site (12). In vivo, in the highly reducing cytoplasm environment, the existence of this intrasubunit disulfide bond points to its very low reduction potential.In addition to the 2 cysteines involved in the formation of the intramolecular disulfide bond, 2 reduced cysteines, Cys-6 and Cys-111, are located on ␤-strand 1 and loop VI of WT human SOD1, respectively. Among the loops connecting the 8 ␤-strands, 2 have structural and functional roles. The ...

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Metal Binding Domains 3 and 4 of the Wilson Disease Protein: Solution Structure and Interaction with the Copper(I) Chaperone HAH1

et al. 2008

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The Wilson disease protein or ATP7B is a P 1B -type ATPase involved in human copper homeostasis. The extended N-terminus of ATP7B protrudes into the cytosol and contains six Cu(I) binding domains. This report presents the NMR structure of the polypeptide consisting of soluble Cu(I) binding domains 3 and 4. The two domains exhibit ferredoxin-like folds, are linked by a flexible loop, and act independently of one another. Domains 3 and 4 tend to aggregate in a concentrationdependent manner involving nonspecific intermolecular interactions. Both domains can be loaded with Cu(I) when provided as an acetonitrile complex or by the chaperone HAH1. HAH1 forms a 70% complex with domain 4 that is in fast exchange with the free protein in solution. The ability of HAH1 to form a complex only with some domains of ATP7B is an interesting property of this class of proteins and may have a signaling role in the function of the ATPases.Human ATP7B (WLN) 1 is a member of the P 1B -type ATPase family that plays a crucial role in copper transport and homeostasis in the body (1). The WLN protein, like the other human copper ATPase, the Menkes protein (MNK hereafter), delivers copper to the secretory pathway of the trans-Golgi network (TGN) where the metal ion is incorporated into copper-dependent enzymes (2,3). Both proteins can also translocate from the Golgi membrane to the plasma membrane for copper efflux from the cell (4-6). The predicted topological organization of † This work was supported by National Institutes of Health Grant GM58518, Integrated Project SPINE2-COMPLEXES n° 031220,

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