Periplasmic fractionation of Escherichia coli yields recombinant plastocyanin despite the absence of a signal sequence

A periplasmic cupredoxin with a green CuT1.5 center is involved in bacterial copper tolerance

The importance of copper resistance pathways in pathogenic bacteria is now well recognized, since macrophages use copper to fight bacterial infections. Additionally, considering the increase of antibiotic resistance, growing attention is given to the antimicrobial properties of copper. It is of primary importance to understand how bacteria deal with copper. The Cu-resistant cuproprotein CopI is present in many human bacterial pathogens and environmental bacteria and crucial under microaerobiosis (conditions for most pathogens to thrive within their host). Hence, understanding its mechanism of function is essential. CopI proteins share conserved histidine, cysteine, and methionine residues that could be ligands for different copper binding sites, among which the cupredoxin center could be involved in the protein function. Here, we demonstrated that Vibrio cholerae and Pseudomonas aeruginosa CopI restore the Cu-resistant phenotype in the Rubrivivax gelatinosus ΔcopI mutant. We identified that Cys125 (ligand in the cupredoxin center) and conserved histidines and methionines are essential for R. gelatinosus CopI (RgCopI) function. We also performed spectroscopic analyses of the purified RgCopI protein and showed that it is a green cupredoxin able to bind a maximum of three Cu(II) ions: (i) a green Cu site (CuT1.5), (ii) a type 2 Cu binding site (T2) located in the N-terminal region, and (iii) a third site with a yet unidentified location. CopI is therefore one member of the poorly described CuT1.5 center cupredoxin family. It is unique, since it is a single-domain cupredoxin with more than one Cu site involved in Cu resistance.

The transient complex of poplar plastocyanin with cytochrome f: effects of ionic strength and pH

The orientation of poplar plastocyanin in the complex with turnip cytochrome f has been determined by rigid-body calculations using restraints from paramagnetic NMR measurements. The results show that poplar plastocyanin interacts with cytochrome f with the hydrophobic patch of plastocyanin close to the heme region on cytochrome f and via electrostatic interactions between the charged patches on both proteins. Plastocyanin is tilted relative to the orientation reported for spinach plastocyanin, resulting in a longer distance between iron and copper (13.9 A). With increasing ionic strength, from 0.01 to 0.11 M, all observed chemical-shift changes decrease uniformly, supporting the idea that electrostatic forces contribute to complex formation. There is no indication for a rearrangement of the transient complex in this ionic strength range, contrary to what had been proposed earlier on the basis of kinetic data. By decreasing the pH from pH 7.7 to pH 5.5, the complex is destabilized. This may be attributed to the protonation of the conserved acidic patches or the copper ligand His87 in poplar plastocyanin, which are shown to have similar pK(a) values. The results are interpreted in a two-step model for complex formation.

Folding of a beta-sheet protein monitored by real-time NMR spectroscopy

At low ionic strength, apoplastocyanin forms an unfolded state under non-denaturing conditions. The refolding of this state is sufficiently slow to allow real-time NMR experiments to be performed. Folding of apoplastocyanin, initiated by the addition of salt and followed by real-time 2D 1H-15N heteronuclear single quantum coherence (HSQC) spectroscopy, is highly cooperative. A concomitant increase in the intensity of both sequential and long-range nuclear Overhauser effects (NOEs) between backbone amide protons in successive acquisitions of 1H-15N HSQC-NOESY-HSQC spectra provides the first direct observation of the development of structure-specific NOEs as a protein folds. Our results show that the local and long-range interactions in the native apoplastocyanin are formed simultaneously, consistent with highly cooperative formation of the native structure.

A designed apoplastocyanin variant that shows reversible folding

Plastocyanin, like many other metalloproteins, does not undergo reversible folding, which is thought to be due to an irreversible conformational change in the copper-binding site. Moreover, apoplastocyanin's ability to adopt a native tertiary structure is highly salt-dependent, and even in high salt, it has an irreversible thermal denaturation. Here, we report a designed apoplastocyanin variant, PCV, that is well folded and has reversible folding in both high and low salt conditions. This variant provides a tractable model for understanding and designing protein beta-sheets.

A poplar plastocyanin mutant suitable for adsorption onto gold surface via disulfide bridge

Aiming to achieve stable immobilization for a redox-active cupredoxin protein onto a gold substrate and its consequent molecular level monitoring by Scanning Tunnelling Microscopy (STM), we introduced a disulphide bridge within poplar plastocyanin, while avoiding the perturbation of its active site. We selected and modified residues Ile-21 to Cys and Glu-25 to Cys by structurally conservative mutagenesis. Optical absorption spectroscopy (UV-Vis), electron paramagnetic resonance (EPR), and resonance raman scattering (RRS) results indicate that the active site of the Ile21Cys, Glu25Cys plastocyanin (PCSS) to a large extent retains the spectroscopic properties of the wild-type protein. Furthermore, the redox midpoint potential of the couple CuII/CuI in PCSS, determined by cyclic voltammetry was found to be +348 mV close to the wild-type value. The STM images display self-assembled PCSS molecules immobilised onto gold substrate. Moreover, the full potentiostatic control of the electron transfer reaction during STM imaging, suggests that the adsorbed molecule maintains essentially its native redox properties.

Effects of codon usage and vector-host combinations on the expression of spinach plastocyanin in Escherichia coli

Spinach plastocyanin has been expressed in Escherichia coli and exported to the periplasmic space. The effects of codon usage, expression system, growth length, and temperature on expression levels in LB medium were investigated. A stretch of codons, rare in E. coli, was identified and replaced with highly expressed codons, increasing the yield by at least 20%. Plastocyanin was more efficiently expressed under the T7 promoter than under the lac promoter. Maximum yields were obtained at 37 degrees C when growing the cells for 16 h after induction. The optimized expression system produced 38 mg holoprotein per liter culture. In this system it was also possible to express plastocyanin in minimal medium, at a yield of 10 mg per liter. N-terminal sequencing and mass spectrometry showed that plastocyanin was correctly processed. The expressed plastocyanin was purified to homogeneity, as shown by an A278/A597 ratio of 1.0, and together with amino acid analysis and the determination of oxidized and total copper contents, both the absorption coefficients for epsilon 278 and for epsilon 597 were determined to be 4700 M-1 cm-1.

Sequence replacements in the central beta-turn of plastocyanin

The role of beta-turns in dictating the structure of a beta-barrel protein is assessed by probing the tolerance of the central beta-turn of poplar plastocyanin to substitution by arbitrary sequences. Native plastocyanin binds copper and is colored bright blue. However, when the wild-type Pro47-Ser48-Gly49-Val50 turn sequence is replaced by arbitrary tetrapeptides, the vast majority (92/98 = 94%) of mutant proteins cannot fold into the native blue structure. Characterization of the colorless mutant proteins demonstrates that the majority of substitutions in this type II beta-turn disrupt the native structure severely. Gross structural changes are indicated by major differences in the CD spectra of the mutants relative to the wild-type protein, and by the much larger apparent size of mutant proteins in gel filtration experiments. These mutant proteins do not bind copper. Furthermore, Cys84 forms a disulfide bond readily in the colorless mutant proteins, indicating that it has moved away from the buried position it occupies in the native copper binding site and has become exposed. These results indicate that the central beta-turn in plastocyanin is not merely a default structure arising in response to the surrounding context; rather, sequence information in this turn plays an active role in dictating the location of a chain reversal in the beta-barrel structure. These findings are discussed in terms of their implications for the folding of natural proteins, as well as the design of de novo proteins.

Recombinant proteins can be isolated from E. coli cells by repeated cycles of freezing and thawing

Repeated cycles of freezing and thawing are sufficient to separate highly expressed recombinant proteins away from the cellular milieu of E. coli. Freezing and thawing liberates recombinant proteins from the bacterial cytoplasm, but does not release the bulk of endogenous E. coli proteins. Furthermore, protein secretion is not required. Fractionation of overexpressed proteins by freeze/thaw treatment does not depend on the identity of the recombinant protein and has been observed for thirty-five different recombinant proteins expressed in E. coli. These include proteins originally found in plant, animal or microbial sources, as well as several proteins designed de novo. Freezing and thawing typically yields approximately 50% of the recombinant protein in relatively pure form. Thus the freeze/thaw treatment can be utilized as a general method for the isolation of recombinant proteins from E. coli.