Studies on plantacyanin. I. Distribution in the plant kingdom, subcellular localization and physicochemical properties

The standard preparative procedure used earlier for the isolation of plantacyanin from cucumber peelings and spinach leaves was employed for the detection of this protein in 15 plants. It was found that four of these 15 species of plants contain plantacyanin. From the study of the subcellular distribution of plantacyanin in spinach leaves, it has been concluded that the protein is associated with chloroplasts. Macromolecular properties as well as optical, fluorescence and EPR spectra of plantacyanin from cucumber were studied. It has been shown that at alkaline pH, a short living state of the protein active site is formed. This state (state 3) has an absorption band at 575 nm. The incubation of the protein in alkaline media under anaerobic conditions brings about the bleaching of plantacyanin accompanied by the disappearance of the EPR signal. The effect of some protein-modifying agents was studied and the data obtained are discussed from the point of view of possible ligand amino acids of copper in plantacyanin. The protein copper can be removed by diethyldithiocarbamate and the procedure of reconstitution of holoprotein from apoprotein and Cu2+ was developed.     

Uclacyanins,stellacyanins, and plantacyanins are distinct subfamilies of phytocyanins: plant-specific mononuclear blue copper proteins.

The cDNAs encoding plantacyanin from spinach were isolated and characterized. In addition, four new cDNA sequences from Arabidopsis ESTs were identified that encode polypeptides resembling phytocyanins, plant-specific proteins constituting a distinct family of mononuclear blue copper proteins. One of them encodes plantacyanin from Arabidopsis, while three others, designated as uclacyanin 1, 2, and 3, encode protein precursors that are closely related to precursors of stellacyanins and a blue copper protein from pea pods. Comparative analyses with known phytocyanins allow further classification of these proteins into three distinct subfamilies designated as uclacyanins, stellacyanins, and plantacyanins. This specification is based on (1) their spectroscopic properties, (2) their glycosylation state, (3) the domain organization of their precursors, and (4) their copper-binding amino acids. The recombinant copper binding domain of Arabidopsis uclacyanin 1 was expressed, purified, and shown to bind a copper atom in a fashion known as "blue" or type 1. The mutant of cucumber stellacyanin in which the glutamine axial ligand was substituted by a methionine (Q99M) was purified and shown to possess spectroscopic properties similar to uclacyanin 1 rather than to plantacyanins. Its redox potential was determined by cyclic voltammetry to be +420 mV, a value that is significantly higher than that determined for the wild-type protein (+260 mV). The available structural data suggest that stellacyanins (and possibly other phytocyanins) might not be diffusible electron-transfer proteins participating in long-range electron-transfer processes. Conceivably, they are involved in redox reactions occurring during primary defense responses in plants and/or in lignin formation.     

Preparation and spectroscopic studies of cobalt(II)-substituted cucumber basic blue protein "plantacyanin"

The cobalt(II) derivative of cucumber basic blue copper protein "plantacyanin" has been prepared. The visible absorption, circular dichroic and magnetic circular dichroic spectra of Co(II)-plantacyanin are similar to those of Co(II)-plastocyanin, indicating that the stereochemistry of Co(II) is tetrahedral and at least one cysteinyl ligand around Co(II) ion is responsible for the strong charge transfer bands at 331 and ca. 390 nm.     

Hydroxyapatite chromatography of the D-glucose transport protein of human erythrocyte membranes

Absorption, circular dichroism, electron spin resonance and resonance Raman spectra of a blue copper protein, plantacyanin from cucumber peel have been measured and these spectral properties compared with those of other blue copper proteins. From the spectral properties, amino acid analysis and redox potential, we discuss the active site and redox properties of this protein.     

Variable selection method improves the prediction of protein secondary structure from circular dichroism spectra

A new procedure based on the statistical method of "variable selection" is used to predict the secondary structure of proteins from circular dichroism spectra. Variable selection adds the flexibility found in the Provencher and Gl?ckner method (S. W. Provencher and J. Gl?ckner, 1981, Biochemistry 20, 33-37) to the method of Hennessey and Johnson (J. P. Hennessey and W. C. Johnson, 1981, Biochemistry 20, 1085-1094). Two analytical methods are presented for choosing a solution from the series generated by the Provencher and Gl?ckner method, and this improves the technique. All three methods are compared and it is shown that both the variable selection method and the improved Provencher and Gl?ckner methods have equivalent reliability superior to the original Hennessey and Johnson method. For the new variable selection method, correlation coefficients calculated between X-ray structure and predicted secondary structures for data measured to 178 nm are: 0.97 for alpha-helix, 0.75 for beta-sheet, 0.50 for beta-turn, and 0.89 for other structures. Although the variable selection method improves the analysis of circular dichroism data truncated at 190 nm, data measured to 178 nm gives superior results. It is shown that improving the fit to the measured CD beyond the accuracy of the data can result in poorer analyses.     

Visible and magnetic circular dichroism studies on cobalt(II)-substituted rhus vernicifera laccase

The visible and magnetic circular dichroism (MCD) spectra of Co(II) derivatives of Rhus vernicifera laccase are reported. Anaerobic incorporation of 1 g-atom of Co(II) into apolaccase gave bands at 528(ϵ = 248), 558 (254) and 589 nm (shoulder) attributable to dd transitions. The MCD spectrum in the corresponding region is similar to that of Co(II)-substituted hemocyanin, indicating that the Co(II) ion incorporated into apolaccase is tetrahedral. On increasing the amount of Co(II) ion acting on the apolaccase, both the intensities of the absorption and the MCD spectra increased, and 2 g-atoms of tetrahedral Co(II) ion were introduced into the apolaccase. Very similar absorption and MCD spectra were obtained when laccase whose type I copper site was occupied by Hg(II) and both type II and type III copper sites were vacant (TlHg apolaccase) was treated with Co(II); this clearly supports the hypothesis that Co(II) cannot be incorporated into a type I copper site but may possibly be incorporated into a type III copper site. A tetrahedral Co(II) ion was also introduced into a type II copper site of type II copper-depleted (T2D) laccase, although its MCD bands were shifted ca. 20 nm to the longer wavelength region from the MCD bands due to tetrahedral Co(II) ion incorporated into type III copper site(s). The present study demonstrate that a tetrahedral Co(II) ion is introduced into type II or type III copper site(s) of laccase.     

Absorption, circular dichroism, magnetic circular dichroism and emission study of rat kidney Cd,Cu-metallothionein

Absorption, circular dichroism (CD), magnetic circular dichroism (MCD) and emission spectra of rat liver and rat kidney cadmium-, zinc- and copper-containing metallothioneins (MT) are reported. The absorption, CD and MCD data of native rat kidney Cd,Cu-MT protein closely resemble data recorded for the rat liver Cd,Zn-MT. This suggests that the major features in all three spectra of the native Cd,Cu-MT are dominated by cadmium-related bands. The CD spectrum of the Cd,Cu-MT recorded at pH 2.7 has the same band envelope that is observed for a Cd,Cu-MT formed in vitro by titration of Cd,Zn-MT with Cu(I), suggesting that the copper occupies the zinc sites in Cd,Cu-MT formed both in vivo and, at low molar ratios, in vitro. Remetallalion of the metallothionein from low pH in the presence of both copper and cadmium results in considerably less cadmium bound to the protein than was present in the native sample. It is suggested that this is due to the effect of the distribution of the copper amongst all available binding sites, thus inhibiting cluster formation by the cadmium. Emission spectra are reported for the first time for a cadmium- and copper-containing metallothionein. An emission band at 610 nm is shown to be a sensitive indicator of Cu(I) binding to metallothionein. Both the native Cd,Cu-MT and a Cd,Cu-MT formed in vitro exhibit an excitation spectrum with a band in the copper-thiolate charge-transfer region.     

Investigating the cause of the alkaline transition of phytocyanins

The phytocyanins are a family of plant cupredoxins that have been subdivided into the stellacyanins, plantacyanins, and uclacyanins. All of these proteins possess the typical type 1 His(2)Cys equatorial ligand set at their mononuclear copper sites, but the stellacyanins have an axial Gln ligand in place of the weakly coordinated Met of the plantacyanins, uclacyanins, and most other cupredoxins. The stellacyanins exhibit altered visible, EPR, and paramagnetic (1)H NMR spectra at elevated pH values and also modified reduction potentials. This alkaline transition occurs with a pK(a) of approximately 10 [Dennison, C., Lawler, A. T. (2001) Biochemistry 40, 3158-3166]. In this study we demonstrate that the alkaline transition has a similar influence on the visible, EPR, and paramagnetic NMR spectra of cucumber basic protein (CBP), which is a plantacyanin. The mutation of the axial Gln95 ligand into a Met in umecyanin (UMC), the stellacyanin from horseradish roots, and the axial Met89 into a Gln in CBP have very limited, yet similar, influence on the pK(a) for the alkaline transition as judged from alterations in visible spectra. The complete removal of the axial ligand in the Met89Val variant of CBP results in a slightly larger decrease in the pK(a) for this effect, but similar spectral alterations are still observed at elevated pH. Thus, the axial Gln ligand is not the cause of the alkaline transition in Cu(II) stellacyanins, and alterations in the active site structures of the phytocyanins have a limited effect on this feature. The conserved Lys residue found adjacent to the axial ligand in the sequences of all phytocyanins, and implicated as the trigger for the alkaline transition, has been mutated to an Arg in UMC. The influence of increasing pH on the spectroscopic properties of Lys96Arg UMC is almost identical to those of the wild type protein, and thus, this residue is not responsible for the alkaline transition. However, a positively charged residue in this position seems to be important for the correct folding of UMC. Other possible triggers for the effects seen in the phytocyanins at elevated pH are discussed along with the relevance of the alkaline transition.     

Spectroscopic characterization of rat kidney Hg,Cu-metallothionein

Absorption, circular dichroism (CD), magnetic circular dichroism (MCD) and emission spectra are reported for rat kidney Hg,Cu-metallothionein isoform 3 isolated following induction of the metallothionein with HgCl2. While the absorption spectrum is featureless, both the CD and MCD spectra show resolved bands that arise from the Cu-thiolate and Hg-thiolate groups. The emission spectrum at 77 K is much more complicated than would be expected for a copper (I)-containing metallothionein. It is suggested the emission only arises from the copper-thiolate groups but that the presence of the mercury results in copper ions in several different environments depending on the nature of the nearest neighbour.     

Magnetic circular dichroism studies of bovine liver catalase.

Absorption, circular dichroism (CD) and magnetic circular dichroism (MCD) spectra of beef liver catalase at pH 5.0 and 6.9, and its complexes with NaF, KCNO, NaCNS, NaN3 and NaCN, have been measured between 250 nm and 700 nm at room temperature. The pH 6.9 native catalase MCD shows the presence of several additional transitions not resolved in the absorption spectrum. While these bands can be seen in the spectra of all the derivatives, with the exception of the cyanide, their relative intensities changes considerably between complexes. Of special interest in the MCD of ferric hemes is the signal intensity at about 400 nm and 620 nm. The data indicate that the MCD intensity at 620 nm increases as the high spin iron porphyrin fraction increases, reaching a maximum with the fluoride complex. The 430 nm band intensity increases as the proportion of low spin iron increases, reaching a maximum with the cyanide complex. The MCD spectra also indicate clearly the existence of spin mixtures in the complexes with CNO-, CNS-, and N3-, where both the 430 nm and 620 nm bands have appreciable intensity. It is significant that despite almost identical absorption spectra the CNS- complex has higher fraction of low spin iron than either the CNO- or the N3- species. The differences between the pH 5 and 6.9 MCD spectra of the native catalase suggest that the environment of the heme centre is sensitive to protonation.     

R-phycoerythrins having two conformations for the same aggregate

The visible circular dichroism (CD) spectrum of an R-phycoerythrin (Porphyra tenera) is composed of several positive bands. The protein in aqueous buffer very slowly exhibits changes in the CD spectrum of its chromophores, a band at 489 nm undergoes an increase in intensity and a red shift. When the band reached a 493 nm maximum, the spectrum became very stable. The aggregation state of the protein did not change during this spectral conversion. The chromophore CD spectrum was also obtained in the presence of a low concentration of urea or sodium thiocyanate, and the identical change in the CD was noted, but the change was much faster. The visible absorption and CD in the far UV spectra were unaffected by urea. Unchanged visible absorption and protein secondary structure (61% alpha helix) contradicted by comparatively salient alterations in the visible CD spectra suggested very subtle structural changes are influencing some of the chromophores. For a second R-phycoerythrin (Gastroclonium coulteri), the CD of the chromophores had a negative band on the blue edge of the spectrum. This is the first negative CD band observed for any R-phycoerythrin. Treatment of this protein with low concentrations of urea produced a change in the visible CD with the negative band being completely converted to a positive band. Fluorescence studies showed that the treatment by urea did not affect energy migration. Deconvolution of the CD spectra were used to monitor the chromophores. The results demonstrated that the same aggregate of each R-phycoerythrin could exist in two conformations, and this is a novel finding for any red algal or cyanobacterial biliprotein. The two forms of each protein would differ in tertiary structure, but retain the same secondary structures.     

Crystal structure of plantacyanin, a basic blue cupredoxin from spinach

The crystal structure of the basic blue protein (plantacyanin) from spinach (SBP) has been solved to a resolution of 2.05 A by molecular replacement using the homologous protein from cucumber (CBP) as a model. Although the sequence identity of 58% between both proteins is only moderate, the three-dimensional structures turned out to be highly similar and the buried residues, which form the hydrophobic core of the protein, are almost completely conserved. However, the redox potentials of both proteins differ by 40 mV, and a comparison of the two structures leads to a single lysine replacing a proline in the cucumber sequence, which causes a shift of the peptide chain and thus a subtle distortion of the copper ligand geometry in respect to CBP. The crystal contained three monomers of SBP in the asymmetric unit which show considerable variations in outer loop regions owing to crystal packing, but not in the regions presumed to be essential for redox partner recognition and redox potential fine tuning of the copper centers. Still, bond length variations at the copper site are at the same scale between the monomers of SBP as they are in respect to CBP, indicating that in the oxidized state the protein does not impose a high conformational strain on the copper.     

Conformational changes in plastocyanin

The visible and near-uv absorption and circular dichroic spectra were determined for spinach and poplar plastocyanin under a variety of conditions. The visible spectra showed that the copper center was invariant to changes in species, chemical modification with ethylenediamine, and addition of high concentrations of salt [2.7 M (NH4)2SO4]. In contrast, the near-uv spectra were sensitive to these conditions. Reduction of plastocyanin also altered its near-uv absorption and circular dichroic spectra. It is unlikely that these spectral changes were due to charge transfer bands since the near-uv CD spectrum of apo-plastocyanin was almost identical to that of reduced plastocyanin. There were no corresponding changes in the far-uv spectra which monitor protein secondary structure. The most likely explanation is that the protein has a flexible tertiary conformation. Conformational changes may be important in regulating electron transport. If plastocyanin is a mobile electron carrier, differential binding of the oxidized and reduced forms of plastocyanin to its reaction partners cytochrome f and P700 could facilitate electron transport.     

Key cofactors of Photosystem II cores from four organisms identified by 1.7-K absorption, CD and MCD

Active Photosystem II (PS II) cores were prepared from spinach, pea, Synechocystis PCC 6803, and Thermosynechococcus vulcanus, the latter of which has been structurally determined [Kamiya and Shen (2003) Proc Natl Acad Sci USA 100: 98–103]. Electrochromic shifts resulting from Q_A reduction by 1.7-K illumination were recorded, and the Q_x and Q_y absorption bands of the redox-active pheophytin a thus identified in the different organisms. The Q_x transition is ∼3 nm (100 cm⁻¹) to higher energy in cyanobacteria than in the plants. The predominant Q_y shift appears in the range 683–686 nm depending on species, and does not appear to have a systematic shift. Low-temperature absorption, circular dichroism (CD) and magnetic circular dichroism (MCD) spectra of the chlorophyll Q_y region are very similar in spinach and pea, but vary in cyanobacteria. We assigned CP43 and CP47 trap-chlorophyll absorption features in all species, as well as a P680 transition. Each absorption identified has an area of one chlorophyll a. The MCD deficit, introduced previously for spinach as an indicator of P680 activity, occurs in the same spectral region and has the same area in all species, pointing to a robustness of this as a signature for P680. MCD and CD characteristics point towards a significant variance in P680 structure between cyanobacteria, thermophilic cyanobacteria, and higher plants.     

Analysis of the near-ultraviolet absorption and circular dichroic spectra of parsley plastocyanin for the effects of pH and copper center conformation changes

The absorption and circular dichroic (CD) spectra of parsley plastocyanin (PC) were measured in order to determine the effects of changes in primary amino acid sequence on both the copper center and protein components of the PC molecule. The near-ultraviolet (uv) absorption and CD spectra of parsley PC were found to be qualitatively similar to those of spinach, poplar, and lettuce PC, except for the near-uv CD spectrum of the reduced form at low pH (ca. pH 5.0). The CD spectrum of reduced parsley PC in the 250-265 nm wavelength region changes from positive to negative ellipticity upon reduction of pH, and is characterized by a pKa value of 5.7. This pKa value is the same as that for the protonation of the histidine 87 copper ligand, observed by NMR, and the change in conformation of the copper center. Similar processes are believed to occur in the other PC species at lower pH values. Thus, the pH-dependent perturbations of the near-uv CD spectra of reduced PC are interpreted as due to transitions in the reduced copper center. The increase in the near-uv absorption spectrum of reduced PC can be divided into pH-independent and pH-dependent portions. The pH-independent portion resembles the absorption spectrum of tetrahedral Cu(I) metallothionein, suggesting the presence of Cu(I)-Cys 84 and/or Cu(I)-Met 92 charge transfer transitions in the near-uv absorption spectra of reduced PC. The pH dependence of the absorption spectrum changes and the pH difference absorption spectrum indicate that tyrosine residues may contribute to at least a part of the pH-dependent portion of the absorption increase of reduced PC.     

Effects of heating at neutral and acid pH on the structure of β-lactoglobulin A revealed by differential scanning calorimetry and circular dichroism spectroscopy

The structural change of β-lactoglobulin A (βLG A) on heating was measured at pH 3.0 and 7.5 with UV absorption difference spectra, differential scanning calorimetry (DSC), and circular dichroism (CD). At pH 3.0, βLG A showed a reversible structural change by heating at 80 °C, while an irreversible change was observed and molecular aggregates of βLG were formed by heating at 95 °C. DSC analysis of βLG A gave endothermic peaks at 75 °C and 90 °C at pH 7.5, and 90 °C at pH 3.0. At pH 7.5, βLG A modified with N-ethylmaleimide (NEM-βLG A) gave two endothermic peaks: at 72 °C and 90 °C. CD spectra of βLG A heated at various temperatures and pHs were measured and the spectra at pH 3.0 and 7.5 were not changed by heating to 95 °C and 80 °C, respectively. Unheated NEM-βLG A gave a spectrum similar to that of heated βLG A, suggesting that the secondary structure was changed by NEM treatment.     

Magnetic circular dichroism of non-heme iron proteins

The magnetic circular dichroism (MCD) at 45 kgauss has been determined for a group of non-heme iron proteins. Both transferrin and conalbumin exhibit a single, positive ellipticity band at 330 nm ([θ]_M = 560). Oxy- and methemerythrin, spinach and clostridial ferredoxins and rubredoxin all display distinctive multibanded spectra which may reflect such factors as coordination of the metal, its ligands, metal bridging by other atoms, and varying degrees of metalmetal coupling. The MCD spectra of both ferredoxins and rubredoxin undergo dramatic change upon oxidoreduction providing a potential means for relating the electronic structure of the iron to protein function. In contrast to the plant ferredoxins, the magnetic field does not significantly affect the CD spectra of adrenodoxin and putidaredoxin.     

Protein secondary structure from Fourier transform infrared spectroscopy: a data base analysis

An infrared (ir) method to determine the secondary structure of proteins in solution using the amide I region of the spectrum has been devised. The method is based on the circular dichroism (CD) matrix method for secondary structure analysis given by Compton and Johnson (L. A. Compton and W. C. Johnson, 1986, Anal. Biochem. 155, 155-167). The infrared data matrix was constructed from the normalized Fourier transform infrared spectra from 1700 to 1600 cm-1 of 17 commercially available proteins. The secondary structure matrix was constructed from the X-ray data of the seventeen proteins with secondary structure elements of helix, beta-sheet, beta-turn, and other (random). The CD and ir methods were compared by analyzing the proteins of the CD and ir databases as unknowns. Both methods produce similar results compared to structures obtained by X-ray crystallographic means with the CD slightly better for helix conformation, and the ir slightly better for beta-sheet. The relatively good ir analysis for concanavalin A and alpha-chymotrypsin indicate that the ir method is less affected by the presence of aromatic groups. The concentration of the protein and the cell path length need not be known for the ir analysis since the spectra can be normalized to the total ir intensity in the amide I region. The ir spectra for helix, beta-sheet, beta-turn, and other, as extracted from the data-base, agree with the literature band assignments. The ir data matrix and the inverse matrix necessary to analyze unknown proteins are presented.     

Expression,purification and spectroscopic characterization of the cytochrome P450 CYP121 from Mycobacterium tuberculosis

The CYP121 gene from the pathogenic bacterium Mycobacterium tuberculosis has been cloned and expressed in Escherichia coli, and the protein purified to homogeneity by ion exchange and hydrophobic interaction chromatography. The CYP121 gene encodes a cytochrome P450 enzyme (CYP121) that displays typical electronic absorption features for a member of this superfamily of hemoproteins (major Soret absorption band at 416.5 nm with alpha and beta bands at 565 and 538 nm, respectively, in the oxidized form) and which binds carbon monoxide to give the characteristic Soret band shift to 448 nm. Resonance Raman, EPR and MCD spectra show the protein to be predominantly low-spin and to have a typical cysteinate- and water-ligated b-type heme iron. CD spectra in the far UV region describe a mainly alpha helical conformation, but the visible CD spectrum shows a band of positive sign in the Soret region, distinct from spectra for other P450s recognized thus far. CYP121 binds very tightly to a range of azole antifungal drugs (e.g. clotrimazole, miconazole), suggesting that it may represent a novel target for these antibiotics in the M. tuberculosis pathogen.     

Electronic structures of azulene-fused porphyrins as seen by magnetic circular dichroism and TD-DFT calculations

A combination of magnetic circular dichroism (MCD), electronic absorption spectroscopy and time-dependent density functional theory (TD-DFT) calculations has been used to investigate the electronic structure of azulene-fused pi-expanded porphyrins based primarily on the spectral properties of absorption bands in the near infrared region. From MCD experiments, it was suggested that in the case of a mono-azulene-fused porphyrin DeltaHOMO approximately equal DeltaLUMO (where DeltaHOMO is the magnitude of the energy gap between the HOMO and HOMO-1 and DeltaLUMO is the magnitude of the energy gap between the LUMO and LUMO+1), while in the case of an oppositely-di-azulene-fused porphyrin, DeltaHOMO相似文献