An NMR view of the unfolding process of rusticyanin: Structural elements that maintain the architecture of a beta-barrel metalloprotein

The unfolding process of the blue copper protein rusticyanin (Rc) as well as its dynamic and D(2)O/H(2)O exchange properties in an incipient unfolded state have been studied by heteronuclear NMR spectroscopy. Titrations of apo, Cu(I), and Cu(II)Rc with guanidinium chloride (GdmCl) show that the copper ion stabilizes the folded species and remains bound in the completely unfolded state. The oxidized state of the copper ion is more efficient than the reduced form in this respect. The long loop of Rc (where the first ligand of the copper ion is located) is one of the most mobile domains of the protein. This region has no defined secondary structure elements and is prone to exchange its amide protons. In contrast, the last loop (including a short alpha-helix) and the last beta-strand (where the other three ligands of the metal ion are located) form the most rigid domain of the protein. The results taken as a whole suggest that the first ligand detaches from the metal ion when the protein unfolds, while the other three ligands remain bound to it. The implications of these findings for the biological folding process of Rc are also discussed.     

Role of DnaJ G/F-rich Domain in Conformational Recognition and Binding of Protein Substrates

DnaJ from Escherichia coli is a Type I Hsp40 that functions as a cochaperone of DnaK (Hsp70), stimulating its ATPase activity and delivering protein substrates. How DnaJ binds protein substrates is still poorly understood. Here we have studied the role of DnaJ G/F-rich domain in binding of several substrates with different conformational properties (folded, partially (un)folded and unfolded). Using partial proteolysis we find that RepE, a folded substrate, contacts a wide DnaJ area that involves part of the G/F-rich region and Zn-binding domain. Deletion of G/F-rich region hampers binding of native RepE and reduced the affinity for partially (un)folded substrates. However, binding of completely unfolded substrates is independent on the G/F-rich region. These data indicate that DnaJ distinguishes the substrate conformation and is able to adapt the use of the G/F-rich region to form stable substrate complexes.     

Methionine-121 coordination determines metal specificity in unfolded<Emphasis Type="Italic"> Pseudomonas aeruginosa</Emphasis> azurin

Pseudomonas aeruginosa azurin binds copper so tightly that it remains bound even upon polypeptide unfolding. Copper can be substituted with zinc without change in protein structure, and also in this complex the metal remains bound upon protein unfolding. Previous work has shown that native-state copper ligands Cys112 and His117 are two of at least three metal ligands in the unfolded state. In this study we use isothermal titration calorimetry and spectroscopic methods to test if the native-state ligand Met121 remains a metal ligand upon unfolding. From studies on a point-mutated version of azurin (Met121Ala) and a set of model peptides spanning the copper-binding C-terminal part (including Cys112, His117 and Met121), we conclude that Met121 is a metal ligand in unfolded copper-azurin but not in the case of unfolded zinc-azurin. Combination of unfolding and metal-titration data allow for determination of copper (Cu(II) and Cu(I)) and zinc affinities for folded and unfolded azurin polypeptides, respectively.     

Respiratory isozyme,two types of rusticyanin of Acidithiobacillus ferrooxidans

Among the members of the copper protein superfamily, the type I enzyme rusticyanin, which is found as an electron carrier in the oxidative respiratory chain of Acidithiobacillus ferrooxidans, is the only one to have both a high redox potential and acid stability. Here we report that two forms of the rusticyanin gene (rus) are present in the genomes of some strains of A. ferrooxidans. The more common form of rus (type-A) was found to be present in all six strains studied, including those harboring only a single copy of the gene. In addition a less common form (type-B) occurred in strains harboring multiple copies of the gene. The two genes were expressed as rusticyanin isozymes with differing surface charges due to differences in their amino acid composition. Still, the copper coordination sites were completely conserved, thereby maintaining the high redox potential necessary for an electron carrier.     

Copper binding before polypeptide folding speeds up formation of active (holo) Pseudomonas aeruginosa azurin.

Cofactors often stabilize the native state of the proteins; however, their effects on folding dynamics remain poorly understood. To uncover the role of one cofactor, we have examined the folding kinetics of Pseudomonas aeruginosa azurin, a small blue-copper protein with a copper cofactor uniquely coordinated to five protein residues. Copper removal produces apo-azurin which adopts a folded structure identical to that of the holo-form. The folding and unfolding kinetics for apo-azurin follow two-state behavior. The extrapolated folding time in water, tau approximately 7 ms, is in good agreement with the topology-based prediction. Copper uptake by folded apo-azurin, to govern active (holo) protein, is slow (tau approximately 14 min, 50:1 copper-to-protein ratio). In contrast, the formation of active (holo) azurin is much faster when copper is allowed to interact with the unfolded polypeptide. Refolding in the presence of 10:1, 50:1, and 100:1 copper:protein ratios yields identical time-trajectories: active azurin forms in two kinetic phases with folding times, extrapolated to water, of tau = 10 +/- 2 ms (major phase) and tau = 190 +/- 30 ms (minor phase), respectively. Correlating copper-binding studies, with a small peptide derived from the metal-binding region of azurin, support that initial cofactor binding is fast (tau approximately 3.7 ms) and thus not rate-limiting. Taken together, introducing copper prior to protein folding does not speed up the polypeptide-folding rate; nevertheless, it results in much faster (> 4000-fold) formation of active (i.e., holo) azurin. Living systems depend on efficient formation of functional biomolecules; attachment of cofactors prior to polypeptide folding appears to be one method to achieve this.     

Amino acid sequence of the blue copper protein rusticyanin from Thiobacillus ferrooxidans

Rusticyanin is a small blue copper protein isolated from Thiobacillus ferrooxidans. The amino acid sequence of the rusticyanin has been determined by the structural characterization of tryptic and endoproteinase Asp-N peptides with use of amino terminal microsequencing, fast atom bombardment mass spectrometry, and electrospray triple-quadrupole mass spectrometry techniques. Amino acid analysis, carboxy-terminal sequence analysis, and circular dichroism spectroscopy were also performed on the protein. Amino acid sequence identity among rusticyanin and six other small blue copper proteins is apparent only in the limited C-terminal region of each protein bearing three of the four putative copper ligands. A structural model of the rusticyanin is proposed where the protein is principally a beta-barrel comprised of six strands. This model is consistent with the circular dichroism data and computational predictions of the secondary structure of rusticyanin. A feature of the model is the hypothesis that Asp 73 may serve as a fourth copper ligand.     

1H nuclear magnetic relaxation dispersion of Cu,Zn superoxide dismutase in the native and guanidinium-induced unfolded forms

Potentialities and limitations of the use of (1)H NMRD technique for the characterization of the hydration properties of unfolded or partially folded states of proteins are discussed. The copper(I) form of monomeric Cu,Zn superoxide dismutase in its folded state and in the presence of 4M guanidinium chloride is taken as case system. The dispersion profile, analyzed with an extended relaxation matrix analysis, indicates the presence of long-lived water molecules in the folded state. The observed increase in relaxation at high field upon addition of guanidinium chloride indicates an increase in the number of solvation protons interacting with the protein and exchanging with a time shorter than the protein reorientational time. The observed effect is consistent with an exposed protein surface of SOD in the presence of 4M guanidinium chloride smaller than what could be expected for a random coil.     

HLA class I allelic sequence and conformation regulate leukocyte Ig-like receptor binding

Leukocyte Ig-like receptors (LILRs) are a family of innate immune receptors predominantly expressed by myeloid cells that can alter the Ag presentation properties of macrophages and dendritic cells. Several LILRs bind HLA class I. Altered LILR recognition due to HLA allelic variation could be a contributing factor in disease. We comprehensively assessed LILR binding to >90 HLA class I alleles. The inhibitory receptors LILRB1 and LILRB2 varied in their level of binding to different HLA alleles, correlating in some cases with specific amino acid motifs. LILRB2 displayed the weakest binding to HLA-B*2705, an allele genetically associated with several autoimmune conditions and delayed progression of HIV infection. We also assessed the effect of HLA class I conformation on LILR binding. LILRB1 exclusively bound folded β(2)-microglobulin-associated class I, whereas LILRB2 bound both folded and free H chain forms. In contrast, the activating receptor LILRA1 and the soluble LILRA3 protein displayed a preference for binding to HLA-C free H chain. To our knowledge, this is the first study to identify the ligand of LILRA3. These findings support the hypothesis that LILR-mediated detection of unfolded versus folded MHC modulates immune responses during infection or inflammation.     

Role of rusticyanin in the electron transport process in Thiobacillus ferrooxidans.

Effect of diethyl dithiocarbamate (DEDC), an antimicrobial agent, on growth of Thiobacillus ferrooxidans, possibly by inhibiting rusticyanin present in the periplasmic space of the microorganism, has been studied to gain more insight into the electron transport chain in the bioleaching process. DEDC is found to form a stable complex with rusticyanin in solution and also in polyacrylamide gel. The spectrum of the complex is identical to that of Cu-DEDC complex, suggesting binding of DEDC with copper moiety of rusticyanin and resulting in inhibition of growth. In vitro reduction of purified rusticyanin by Fe(II) in absence of acid-stable cytochrome c is very slow, indicating the importance of cytochrome c in electron transport. Thus, in the iron oxidation process, acid-stable cytochrome c is the primary acceptor of electron, transferring the electron to rusticyanin at pH 2.0, which, in turn, affects electron transfer to iron-cytochrome c reductase around pH 5.5.     

Equilibrium dissociation and unfolding of the Arc repressor dimer

The equilibrium unfolding reaction of Arc repressor, a dimeric DNA binding protein encoded by bacteriophage P22, can be monitored by fluorescence or circular dichroism changes. The stability of Arc is concentration dependent, and the unfolding reaction is well described as a two-state transition from folded dimer to unfolded monomer. The stability of the protein is decreased at low pH and increased by high salt concentration. The salt dependence suggests that two ions bind preferentially to the folded protein. In 10 mM potassium phosphate (pH 7.3) and 100 mM KCl, the unfolding free energy reaches a maximum near room temperature. The results suggest that at the low protein concentrations where operator DNA binding is normally measured, Arc is predominantly monomeric and unfolded.     

Solution structures of the reduced and Cu(I) bound forms of the first metal binding sequence of ATP7A associated with Menkes disease

The coding sequence for the first N-terminal copper binding motif of the human Menkes disease protein (MNK1; residues 2-79) was synthesized, cloned, and expressed in bacteria for biochemical and structural studies. MNK1 adopts the betaalphabetabetaalphabeta fold common to all the metal binding sequences (MBS) found in other metal transport systems (e.g., the yeast copper chaperone for superoxide dismutase CCS, the yeast copper chaperone ATX1 bound to Hg(II), and most recently Cu(I), the bacterial copper binding protein, CopZ, and the bacterial Hg(II) binding protein MerP), although substantial differences were found in the metal binding loop. Similar to ATX1, MNK1 binds Cu(I) in a distorted linear bicoordinate geometry. As with MerP, MNK1 has a high affinity for both Hg(II) and Cu(I), although it displays a marked preference for Cu(I). In addition, we found that F71 is a key residue in the compact folding of MNK1, and its mutation to alanine results in an unfolded structure. The homologous residue in MerP has also been mutated with similar results. Finally, to understand the relationship between protein folding and metal affinity and specificity, we expressed a chimeric MBS with the MNK1 protein carrying the binding motif of MerP (CAAC-MNK1); this chimeric protein showed differences in structure and the dynamics of the binding site that may account for metal specificity.     

Solution structure of the N-terminal domain of a potential copper-translocating P-type ATPase from Bacillus subtilis in the apo and Cu(I) loaded states

A putative partner of the already characterized CopZ from Bacillus subtilis was found, both proteins being encoded by genes located in the same operon. This new protein is highly homologous to eukaryotic and prokaryotic P-type ATPases such as CopA, Ccc2 and Menkes proteins. The N-terminal region of this protein contains two soluble domains constituted by amino acid residues 1 to 72 and 73 to 147, respectively, which were expressed both separately and together. In both cases only the 73-147 domain is folded and is stable both in the copper(I)-free and in the copper(I)-bound forms. The folded and unfolded state is monitored through the chemical shift dispersion of 15N-HSQC spectra. In the absence of any structural characterization of CopA-type proteins, we determined the structure of the 73-147 domain in the 1-151 construct in the apo state through 1H, 15N and 13C NMR spectroscopies. The structure of the Cu(I)-loaded 73-147 domain has been also determined in the construct 73-151. About 1300 meaningful NOEs and 90 dihedral angles were used to obtain structures at high resolution both for the Cu(I)-bound and the Cu(I)-free states (backbone RMSD to the mean 0.35(+/-0.06) A and 0.39(+/-0.07) A, respectively). The structural assessment shows that the structures are accurate. The protein has the typical betaalpha(betabeta)alphabeta folding with a cysteine in the C-terminal part of helix alpha1 and the other cysteine in loop 1. The structures are similar to other proteins involved in copper homeostasis. Particularly, between BsCopA and BsCopZ, only the charges located around loop 1 are reversed for BsCopA and BsCopZ, thus suggesting that the two proteins could interact one with the other. The variability in conformation displayed by the N-terminal cysteine of the CXXC motif in a number of structures of copper transporting proteins suggests that this may be the cysteine which binds first to the copper(I) carried by the partner protein.     

An amicyanin C-terminal loop mutant where the active-site histidine donor cannot be protonated

A novel blue copper protein was constructed by replacing the C-terminal loop of amicyanin (Paracoccus versutus) by the homologous loop of rusticyanin. The C-terminal loop of both amicyanin and rusticyanin contains three (His, Cys, Met) of the four copper ligands. The amicyanin mutant exhibits all spectroscopic properties normally encountered for blue copper sites. The midpoint potential (369 mV) is the highest reported value for an amicyanin mutant. Cyclic voltammetry and NMR studies of the reduced form indicate that, in contrast to wild-type amicyanin and all amicyanin mutants described so far, the C-terminal histidine ligand does not protonate in the accessible pH range (pKa<4.5).     

Natively unfolded domains in endocytosis: hooks, lines and linkers

It is commonly assumed that a protein must adopt a tertiary structure to achieve its active native state and that regions of a protein that are devoid of alpha-helix or beta-sheet structures are functionally inert. Although extended proline-rich regions are recognized as presenting binding motifs to, for example, Src homology 2 (SH2) and SH3 domains, the idea persists that natively unfolded regions in functional proteins are simply 'spacers' between the folded domains. Such a view has been challenged in recent years and the importance of natively unfolded proteins in biology is now being recognized. In this review, we highlight the role of natively unfolded domains in the field of endocytosis, and show that some important endocytic proteins lack a traditionally folded structure and harbour important binding motifs in their unstructured linker regions.     

The sulfhydryl group of Cys138 of rusticyanin from Acidithiobacillus ferrooxidans is crucial for copper binding

Rusticyanin is a small blue copper protein isolated from Acidithiobacillus ferrooxidans with extreme acid stability and redox potential. The protein is thought to be a principal component in the iron respiratory electron transport chain in this microorganism, but its exact role in electron transfer remains controversial. The gene of rusticyanin was cloned then overexpressed in Escherichia coli, the soluble protein was purified by one-step affinity chromatography to apparent homogeneity. It was reported that Cys138, His85 and His143 were important residues for copper binding, but the significance of Cys138 was not verified so far. We constructed the mutant expression plasmids of these three residues using site-directed mutagenesis. Mutant proteins were expressed in E. coli and purified with a nickel metal affinity column. The EPR and atomic absorption spectroscopy results confirmed that Cys138 was crucial for copper binding. Removal of the sulfhydryl group of Cys138 resulted in copper loss. Mutations of His85 and His143 showed little effect on copper binding.     

Bacterial sec-translocase unfolds and translocates a class of folded protein domains

It is generally assumed that preprotein substrates must be presented in an unfolded state to the bacterial Sec-translocase in order to be translocated. Here, we have examined the ability of the Sec-translocase to translocate folded preproteins. Tightly folded human cardiac Ig-like domain I27 fused to the C terminus of proOmpA is translocated efficiently by the Sec-translocase and the translocation kinetics are determined by the extent of folding of the titin I27 domain. Accumulation of specific translocation intermediates around the fusion point that undergo translocation progress upon ATP binding suggests that the motor protein SecA plays an important and decisive role in promoting unfolding of the titin I27 domain. It is concluded that the bacterial Sec-translocase is capable of actively unfolding preproteins.     

Effect of divers anions on the electron-transfer reaction between iron and rusticyanin from Thiobacillus ferrooxidans

Rusticyanin is a soluble blue copper protein found in abundance in the periplasmic space of Thiobacillus ferrooxidans, an acidophilic bacterium capable of growing chemolithotrophically on soluble ferrous sulfate. The one-electron-transfer reactions between soluble iron and purified rusticyanin were studied by stopped-flow spectrophotometry in acidic solutions containing each of 14 different anions. The second-order rate constants for both the Fe(II)-dependent reduction and the Fe(III)-dependent oxidation of the rusticyanin varied as a function of the identity of the principal anion in solution. Analogous electron-transfer reactions between soluble iron and bis(dipicolinato)cobaltate(III) or bis(dipicolinato)ferrate(II) were studied by stopped-flow spectrophotometry under solution conditions identical with those of the rusticyanin experiments. Similar anion-dependent reactivity patterns were obtained with soluble iron whether the other reaction partner was rusticyanin or either of the two organometallic complexes. The Marcus theory of outer-sphere electron transfer reactions was applied to this set of kinetic data to demonstrate that the rusticyanin may possess at least two electron-transfer pathways for liganded iron, one where the pattern of electron-transfer reactivity is controlled largely by protein-independent activation parameters and one where the protein exhibits an anion-dependent kinetic specificity. The exact role of rusticyanin in the iron-dependent respiratory electron transport chain of T. ferrooxidans remains unclear.     

In-cell NMR in E. coli to monitor maturation steps of hSOD1

In-cell NMR allows characterizing the folding state of a protein as well as posttranslational events at molecular level, in the cellular context. Here, the initial maturation steps of human copper, zinc superoxide dismutase 1 are characterized in the E. coli cytoplasm by in-cell NMR: from the apo protein, which is partially unfolded, to the zinc binding which causes its final quaternary structure. The protein selectively binds only one zinc ion, whereas in vitro also the copper site binds a non-physiological zinc ion. However, no intramolecular disulfide bridge formation occurs, nor copper uptake, suggesting the need of a specific chaperone for those purposes.     

Reduction potentials of blue and purple copper proteins in their unfolded states: a closer look at rack-induced coordination

 Cyclic voltammetry has been used to determine the reduction potentials of blue (Pseudomonas aeruginosa azurin) and purple (Thermus thermophilus Cu_A domain) copper proteins unfolded by guanidine hydrochloride. These Cu(II/I) potentials [456 (azurin); 453 (Cu_A) mV vs., NHE] are higher than those of the folded proteins. The downshift of the potential in the folded state can be accounted for by assuming that rack-induced axial coordination stabilizes Cu(II) relative to Cu(I) in a protein-encapsulated active site. Received: 3 March 1998 / Accepted: 6 April 1998     

Protein folding and binding in confined spaces and in crowded solutions

Simple theoretical models are presented to illustrate the effects of spatial confinement and macromolecular crowding on the equilibria and rates of protein folding and binding. Confinement is expected to significantly stabilize the folded state, but for crowding only a marginal effect on protein stability is expected. In confinement the unfolded chain is restricted to a cage but in crowding the unfolded chain may explore different interstitial voids. Because confinement and crowding eliminate the more expanded conformations of the unfolded state, folding from the compact unfolded state is expected to speed up. Crowding will shift the binding equilibrium of proteins toward the bound state. The significant slowing down in protein diffusion by crowding, perhaps beneficial for chaperonin action, could result in a decrease in protein binding rates.