Inhibition of bovine plasma amine oxidase by superoxide dismutase active Cu(II) complexes

Aqueous Cu²⁺ and Cu(II) complexes of salicylate, lysine, and tyrosine decrease the rate of benzylamine oxidation by bovine plasma amine oxidase. Bissalicylato Cu(II) and Cu²⁺ inhibit non-competitively with respect to benzylamine. Lysine, tyrosine, Cu(EDTA)^2?, Zn²⁺, and Co²⁺ do not inhibit, and erythrocyte Cu, Zn superoxide dismutase shows only slight inhibition of the amine oxidase. The data are most consistent with an inhibitory mechanism involving dismutation of O₂^? by the Cu(II) complexes within a site relatively inaccessible to the enzyme superoxide dismutase. Excess lysine significantly decreases inhibition by the bis-lysine complex of Cu(II).     

Cu(II) transfer into apo-Cu2Zn2-superoxide dismutase from Cu-thionein oxidized by activated leukocytes

The leukocyte-induced oxidative cleavage of yeast Cu(I)-thionein was examined. Oxidation was followed by the progressive decline of the specific Cotton bands attributed to the Cu(I)-thiolate chromophores between 400 and 270 nm. Despite many potent and competitive copper binding sites certainly present in leukocytes, the reconstitution of apo-Cu₂Zn₂-superoxide dismutase was expected due to its higher thermodynamic stability. Both enzymic activity measurements and characteristic Cu(II) EPR properties of Cu₂Zn₂-superoxide dismutase supported a successful reconstitution. The most favoured pathway for releasing Cu(II) from Cu-thionein was suggested to be an enzyme- controlled oxidation.     

Secondary structure dependent on metal ions of copper,zinc superoxide dismutase investigated by Fourier transform IR spectroscopy

Copper,zinc superoxide dismutase (Cu₂Zn₂-SOD) from bovine erythrocyte and its metal ion free derivatives, E₂Zn₂-SOD, Cu₂E₂-SOD, and E₂E₂-SOD (E: empty) were prepared and their secondary structures were investigated by Fourier transform ir spectroscopy. In 20 m M deuterated phosphate buffer (pD 7.5) solution at room temperature, the native Cu₂Zn₂-SOD contains about 34% β-strand, 17% β-turn, and 49% unordered structures, which is similar to the content determined by x-ray crystal structural analysis. The metal ion free derivatives decrease the component of β-strand and increase the unordered structure component in trend. Especially in the cases of zinc-free derivatives, Cu₂E₂-SOD and E₂E₂-SOD, about 24% β-strand, 20% β-turn, and 57% unordered structures are obtained. The result indicates that the zinc ion plays an important role in determining the secondary structure of copper,zinc superoxide dismutase. © 1997 John Wiley & Sons, Inc. Biopoly 42: 297–303, 1997     

Copper and zinc binding properties of the N-terminal histidine-rich sequence of Haemophilus ducreyi Cu,Zn superoxide dismutase

The Cu,Zn superoxide dismutase (Cu,ZnSOD) isolated from Haemophilus ducreyi possesses a His-rich N-terminal metal binding domain, which has been previously proposed to play a copper(II) chaperoning role. To analyze the metal binding ability and selectivity of the histidine-rich domain we have carried out thermodynamic and solution structural analysis of the copper(II) and zinc(II) complexes of a peptide corresponding to the first 11 amino acids of the enzyme (H₂N-HGDHMHNHDTK-OH, L). This peptide has highly versatile metal binding ability and provides one and three high affinity binding sites for zinc(II) and copper(II), respectively. In equimolar solutions the MHL complexes are dominant in the neutral pH-range with protonated lysine ε-amino group. As a consequence of its multidentate nature, L binds zinc and copper with extraordinary high affinity (K_D,Zn = 1.6 × 10⁻⁹ M and K_D,Cu = 5.0 × 10⁻¹² M at pH 7.4) and appears as the strongest zinc(II) and copper(II) chelator between the His-rich peptides so far investigated. These K_D values support the already proposed role of the N-terminal His-rich region of H. ducreyi Cu,ZnSOD in copper recruitment under metal starvation, and indicate a similar function in the zinc(II) uptake, too. The kinetics of copper(II) transfer from L to the active site of Cu-free N-deleted H. ducreyi Cu,ZnSOD showed significant pH and copper-to-peptide ratio dependence, indicating specific structural requirements during the metal ion transfer to the active site. Interestingly, the complex CuHL has significant superoxide dismutase like activity, which may suggest multifunctional role of the copper(II)-bound N-terminal His-rich domain of H. ducreyi Cu,ZnSOD.     

Imidazolate-bridged dicopper(II) and copper(II)–zinc(II) complexes of macrocyclic ligand with methylimidazol pendants: Model study of copper(II)–zinc(II) superoxide dismutase

Two new homo- and hetero-dinuclear complexes, [Cu₂L(im)](ClO₄)₃4H₂O (1) and [CuZnL(im)](ClO₄)₃4H₂O (2) (where Im=1H-1midazole and L = 3, 6, 9, 16, 19, 22-hexaaza-6, 19-bis(1H-imidazol-4-ylmethyl)tricycle[22, 2, 2, 2^11,14]triaconta-1, 11, 13, 24, 27, 29-hexaene) were synthesized and characterized as model compounds for the active site of copper(II)–zinc(II) superoxide dismutase (Cu₂Zn₂–SOD). X-ray crystal structure analysis revealed that the metal centers in both complexes exhibit distorted trigonal-bipyramid coordination geometry and the CuCu and CuZn distances are both 6.02 Å. Magnetic and ESR spectral measurements of 1 showed antiferromagnetic exchange interactions between the imidazolate-bridged Cu(II) ions. The ESR spectrum of 2 displays typical signals of mononuclear Cu(II) complex, demonstrating the formation of heterodinuclear complex 2 rather than a mixture of homodinuclear Cu(II)/Zn(II) complexes. pH-dependent ESR and UV–visible spectral measurements manifest that the imidazolate exists as a bridging ligand from pH 6 to 11 for both complexes. The IC₅₀ values of 1.96 and 1.57 μM [per Cu(II) ion] for 1 and 2 suggest that they are good models for the Cu₂Zn₂–SOD.     

A five-coordinate copper complex with superoxide dismutase mimetic activity fromStreptomyces antibioticus

Summary A Cu(II) complex of desferrithiocin fromStreptomyces antibioticus was prepared and characterized. The first shell atoms, including one nitrogen and four oxygens, were arranged around the copper in a square-planar pyramide. Due to the axially Jahn-Teller-distorted Cu-O distance at 224.7 pm, a distinct Cu₂Zn₂superoxide dismutase mimetic activity was measured. The Cu-complex survived 600 M bovine serum albumin and the thermodynamic stability (pK=17.4) was not very different from that of Cu-EDTA. The electronic absorption properties, circular dichroism and electron paramagnetism were in accordance with those of the type-II copper species.     

On the possible roles of N-terminal His-rich domains of Cu,Zn SODs of some Gram-negative bacteria

The Cu,Zn superoxide dismutases (Cu,Zn SOD) isolated from some Gram-negative bacteria possess a His-rich N-terminal metal binding extension. The N-terminal domain of Haemophilus ducreyi Cu,Zn SOD has been previously proposed to play a copper(II)-, and may be a zinc(II)-chaperoning role under metal ion starvation, and to behave as a temporary (low activity) superoxide dismutating center if copper(II) is available. The N-terminal extension of Cu,Zn SOD from Actinobacillus pleuropneumoniae starts with an analogous sequence (HxDHxH), but contains considerably fewer metal binding sites. In order to study the possibility of the generalization of the above mentioned functions over all Gram-negative bacteria possessing His-rich N-terminal extension, here we report thermodynamic and solution structural analysis of the copper(II) and zinc(II) complexes of a peptide corresponding to the first eight amino acids (HADHDHKK-NH₂, L) of the enzyme isolated from A. pleuropneumoniae. In equimolar solutions of Cu(II)/Zn(II) and the peptide the MH₂L complexes are dominant in the neutral pH-range. L has extraordinary copper(II) sequestering capacity (K_D,Cu = 7.4 × 10^− 13 M at pH 7.4), which is provided only by non-amide (side chain) donors. The central ion in CuH₂L is coordinated by four nitrogens {NH₂,3N_im} in the equatorial plane. In ZnH₂L the peptide binds to zinc(II) through a {NH₂,2N_im,COO⁻} donor set, and its zinc binding affinity is relatively modest (K_D,Zn = 4.8 × 10^− 7 M at pH 7.4). Consequently, the presented data do support a general chaperoning role of the N-terminal His-rich region of Gram-negative bacteria in copper(II) uptake, but do not confirm similar function for zinc(II). Interestingly, the complex CuH₂L has very high SOD-like activity, which may further support the multifunctional role of the copper(II)-bound N-terminal His-rich domain of Cu,Zn SODs of Gram-negative bacteria. The proposed structure for the MH₂L complexes has been verified by semiempirical quantum chemical calculations (PM6), too.     

重金属铜、锌、镉复合胁迫对麻疯树幼苗生理生化的影响

该研究以Cu~(2+)、Zn~(2+)、Cd~(2+)单一胁迫为对照,探讨不同浓度的Cu~(2+)、Zn~(2+)、Cd~(2+)复合胁迫对麻疯树幼苗生理生化指标的影响。结果表明:随着Cu~(2+)、Zn~(2+)、Cd~(2+)浓度的增加,麻疯树幼苗叶片中的蛋白质(Pro)、丙二醛(MDA)含量均逐渐增加,其叶片叶绿素含量随着Zn~(2+)胁迫浓度的增加呈现出先降后升的趋势,在中等浓度(100 mg·L-1)的Zn~(2+)胁迫时含量最低、随着Cu~(2+)胁迫浓度的增加叶绿素含量先升高后降低,在Cu~(2+)浓度为200 mg·L-1时含量最高,达到1 200 mg·g-1FW; Cd~(2+)胁迫对叶绿素含量和根系活力无明显影响。根系活力在Zn~(2+)浓度为100 mg·L~(-1)时最强,随着Cu~(2+)浓度的增加而减弱。低浓度的Cu~(2+)、Zn~(2+)、Cd~(2+)对过氧化物酶活性和可溶性糖含量都具有促进作用。Cu~(2+)、Zn~(2+)、Cd~(2+)复合胁迫时对可溶性蛋白、叶绿素和丙二醛含量均无明显影响,随着复合胁迫时浓度的增加,可溶性糖含量和根系活力先增后减。这表明麻疯树对三种重金属的胁迫具有一定的抗性,过高浓度的胁迫会影响麻疯树幼苗生理生化的一些指标,但是麻疯树可以通过自身的防御系统使伤害降到最小。此外,重金属复合胁迫可以在一定程度上减轻单一胁迫对麻疯树幼苗造成的毒害作用。     

1H-NMR and relaxometry of copper-containing dimers in proteins

Summary The water-proton nuclear-magnetic-relaxation dispersion profiles have been analyzed for Cu₂Zn₂-superoxide dismutase (SOD) and Cu₂-alkaline phosphatase (AP). The electronic relaxation times are derived, together with structural information. The effect of magnetic coupling with another copper ion in Cu₂Cu₂SOD and Cu₂Cu₂AP is discussed. It is shown that the electronic relaxation times of copper(II) essentially do not change. The opposite happens with Cu₂Co₂SOD, Cu₂Co₂AP and Cu₂Ni₂SOD in which fast-relaxing metal ions provide relaxation mechanisms for copper(II) as well. In these cases the systems can be studied through high-resolution NMR spectroscopy.     

Pulse radiolytically determined superoxide dismutase mimicking activity of copper-putrescine-pyridine,a diSchiff base coordinated copper complex

In order to exclude possible interferences in the many indirect superoxide dismutase (SOD) activity measurements using the copper-putrescine-pyridine complex (Cu-PuPy) a pulse radiolytic study on this diSchiff base copper complex has been devised and sucessfully performed. The reaction kinetics and rate constants of pulse radiolytically generated superoxide in the presence of Cu-PuPy reveal pseudo first-order characteristics. The rate constant (k ₂ = 6 ± 1 × 10⁸ m ^–1 s ^–1) is comparable to that of an Fe-SOD and is approximately a factor of 3 lower than that of bovine Cu₂Zn₂-SOD. The superoxide dismutating activity of Cu-PuPy shows a more pronounced temperature dependence compared with that of Cu₂Zn₂-SOD. Arrhenius analyses yielded activation energies of 7.8 ±0.3 and 4.6 ± 0.2 kcal mol^–1 for Cu-PuPy and Cu₂Zn₂-SOD, respectively. The rate constant of the reaction of superoxide and Cu-PuPy is highest at pH 5.0. The possible application of Cu-PuPy for new therapeutic strategies on all types of inflammatory diseases appears to be promising.     

Comparison of the catalytic oxidation of cysteine and o-dianisidine by cupric ion and ceruloplasmin

Several features of the catalytic oxidation of cysteine by ceruloplasmin and nonenzymic Cu(II) at pH 7 have been compared. The oxidation of cysteine by ceruloplasmin has several properties in common with the Cu(II) catalyzed oxidation of cysteine: pH maxima, thiol specificity, lack of inhibition by anions, and high sensitivity to inhibition by copper complexing reagents. These two catalysts differed in their molecular activity, in their ability to oxidize penicillamine and thioglycolate, and in that H₂O₂ was produced as a primary product only during Cu(II) oxidation. The oxidation of cysteine by ceruloplasmin was compared also with the ceruloplasmin catalyzed oxidation of o-dianisidine, a classical pH 5.5 substrate. The mechanism of the oxidation of cysteine by ceruloplasmin at pH 7 differed from that of o-dianisidine oxidation because the latter substrate was inhibited by anions but not by copper complexing agents. Spectral and other data suggest that during the ceruloplasmin reaction with cysteine there is a one electron transfer from cysteine to ceruloplasmin resulting in the specific reduction of type lb Cu(II).     

The Analysis of Cu(II)/Zn(II) Cyclopeptide System as Potential Cu,ZnSOD Mimic Center

In this paper are presented the features of copper (II) and zinc (II) heteronuclear complexes of the cyclic peptide—c(HKHGPG)₂. The coordination properties of ligand were studied by potentiometric, UV–Vis and CD spectroscopic methods. These experiments were carried out in aqueous solutions at 298 K depending on pH. It turned out that in a physiological pH dominates Cu(II)/Zn(II) complex ([CuZnL]⁴⁺) which could mimic the active center of superoxide dismutase (Cu,ZnSOD). In next step we performed in vitro research on Cu,ZnSOD activity for [CuZnL]⁴⁺ complex existing in 7.4 pH by the method of reduction of nitroblue tetrazolium (NBT). Also mono- and di-nuclear copper (II) complexes of this ligand were examined. The ability of inhibition free radical reaction were compared for all complexes. The results of these studies show that Cu(II) mono-, di-nuclear and Cu(II)/Zn(II) complexes becoming to new promising synthetic superoxide dismutase mimetics, and should be considered for further biological assays.     

Orally active antioxidative copper(II) aspirinate: synthesis, structure characterization, superoxide scavenging activity, and in vitro and in vivo antioxidative evaluations

Ever since it was proposed that reactive oxygen species (ROS) are involved in the pathogeneses of various diseases, superoxide dismutase (SOD)-mimetic complexes have been intensively studied. We prepared copper(II) aspirinate [Cu₂(asp)₄] from Cu(II) and aspirin, which has been in use for many years as an antipyretic, an analgesic, and an anti-inflammatory agent. However, Cu₂(asp)₄ has been found to have additional activities, including anti-inflammatory, antiulcer, anti-ischemic/reperfusion agent, anticancer, antimutagenic, and antimicrobial activities. The activity of copper salicylate [Cu(sal)₂] was also compared with that of Cu₂(asp)₄. The structure of the Cu₂(asp)₄ was determined using X-ray structure analysis. Its SOD-mimetic activity was determined using cytochrome c, electron spin resonance (ESR) spectroscopy, and ESR spin trap methods. The activity of Cu₂(asp)₄ was slightly greater than CuSO₄ and copper acetate [Cu(ace)₂] and slightly less than that of Cu(sal)₂. The in vitro antioxidant activity, evaluated in human epithelial or transformed neoplastic keratinocyte cells, HaCaT, and normal dermal fibroblasts in terms of cell survival following ultraviolet B (UVB) irradiation, was significantly increased in the presence of Cu₂(asp)₄, Cu(sal)₂, and CuSO₄. Further, ROS generation following UVA irradiation in the skin of hairless mice following oral treatment with Cu₂(asp)₄ for three consecutive days was significantly suppressed compared to the vehicle- or Cu(ace)₂-treated mice. On the basis of these results, Cu₂(asp)₄ was observed to be a potent antioxidative compound possessing antioxidative activity in biological systems. In conclusion, Cu₂(asp)₄ is a potent antioxidative agent that may be useful for future treatment of diseases resulting from ROS.     

A facilitated electron transfer of copper–zinc superoxide dismutase (SOD) based on a cysteine-bridged SOD electrode

The direct electrochemical redox reaction of bovine erythrocyte copper–zinc superoxide dismutase (Cu₂Zn₂SOD) was clearly observed at a gold electrode modified with a self-assembled monolayer (SAM) of cysteine in phosphate buffer solution containing SOD, although its reaction could not be observed at the bare electrode. In this case, SOD was found to be stably confined on the SAM of cysteine and the redox response could be observed even when the cysteine-SAM electrode used in the SOD solution was transferred to the pure electrolyte solution containing no SOD, suggesting the permanent binding of SOD via the SAM of cysteine on the electrode surface. The electrode reaction of the SOD confined on the cysteine-SAM electrode was found to be quasi-reversible with the formal potential of 65±3 mV vs. Ag/AgCl and its kinetic parameters were estimated: the electron transfer rate constant k_s is 1.2±0.2 s⁻¹ and the anodic (α_a) and cathodic (α_c) transfer coefficients are 0.39±0.02 and 0.61±0.02, respectively. The assignment of the redox peak of SOD at the cysteine-SAM modified electrode could be sufficiently carried out using the native SOD (Cu₂Zn₂SOD), its Cu- or Zn-free derivatives (E₂Zn₂SOD and Cu₂E₂SOD, E designates an empty site) and the SOD reconstituted from E₂Zn₂SOD and Cu²⁺. The Cu complex moiety, the active site for the enzymatic dismutation of the superoxide ion, was characterized to be also the electroactive site of SOD. In addition, we found that the SOD confined on the electrode can be expected to possess its inherent enzymatic activity for dismutation of the superoxide ion.     

Engineering of betabellin 15D: Copper(II)-induced folding of a fibrillar β-sandwich protein

Summary The inverse protein-folding problem has been explored by designing de novo the betabellin target structure (a 64-residue β-sandwich protein), synthesizing a 32-residue peptide chain (HSLTAKIpkLTFSIAphTYTCAVpkYTAKVSH, wherep=DPro,k=DLys, andh=DHis) that might fold into this structure, and studying how its disulfide-bridged form (betabellin 15D) folds in 10 mM ammonium acetate with and without Cu²⁺. Circular dichroic spectropolarimetry indicated that at pH 5.8, 6.4, or 6.7 betabellin 15D exhibited β-sheet structure in the presence of Cu²⁺ but not in its absence. Electrospray mass spectrometry demonstrated that at pH 6.3 each molecule of betabellin 15D bound one or two Cu(II) ions. Electron microscopy showed that at pH 6.7 betabellin 15D formed short broad fibrils in the presence of Cu²⁺ but not in its absence. The observed width of the fibrils (7±2 nm) was consistent with the width (6.8nm) of a structural model of a fibril that contained two adjacent rows of betabellin 15D β-sandwiches joined lengthwise by multiple intersheet hydrogen bonds and widthwise by multiple Cu(II)-imidazole bonds. Electron paramagnetic resonance spectrometry revealed that some pairs of Cu(II) ions in a Cu(II)/betabellin 15D complex were magnetically coupled, which is consistent with the structural model of the Cu(II)/betabellin 15D fibril.     

Purification and Characterization of Cu,Zn Superoxide Dismutase from Ark Shell Scapharca broughtonii

A superoxide dismutase has been purified to apparent homogeneity from the muscular tissue of the ark shell, Scapharca broughtonii, by ammonium sulfate fractionation, and consecutive column chromatographies using DEAE-Sephadex and Sephadex G-100. This enzyme has a molecular weight of 71,700 and is composed of two identical subunits of M _r 35,800, which are joined by noncovalent interactions. The purified enzyme was stable over the range of pH 5.0-10.0 at 4°C for 24 h and at temperatures below 45°C. Cyanide at 0.1 and 1 mM inhibited the activity of the superoxide dismutase 56 and 100%, but 5 mM azide caused 8% inhibition. The optical spectrum of this enzyme had a maximum at 265 nm, and the amino acid composition of the enzyme was similar to that of the other Cu, Zn superoxide dismutases except for the contents of threonine, serine, proline, and leucine. Atomic absorption spectroscopy showed that this enzyme has approximately 2 atoms of Cu²⁺ and Zn²⁺ per mole of enzyme. These results indicate that the purified enzyme from ark shell, Scapharca broughtonii, is a Cu, Zn superoxide dismutase.     

Nodulin-35: a subunit of specific uricase (uricase II) induced and localized in the uninfected cells of soybean nodules

Nodulin-35, a protein specific to soybean root nodules, was purified under non-denaturing conditions (DEAE-cellulose followed by Sephacryl S-200 chromatography) to homogeneity. The holoprotein showed uricase (EC 1.7.3.3) activity. Analytical ultracentrifugation under non-denaturing conditions revealed a molecule of 124 kd, S°_20W = 8.1; however, under denaturing conditions a value of 33 kd, S°_20W = 1.9, was obtained. This indicated that nodulin-35 is the 33-kd subunit of a specific soybean root nodule uricase (uricase II) and that the enzyme contains four similar subunits. The native molecule contains ˜1.0 mol Cu²⁺ per mol, has an isoelectric point of ˜9.0 and a pH optimum for uricase activity at 9.5. Uricase activity found in young uninfected soybean roots is due to another form of enzyme (uricase I) which is of ˜190 kd, has maximum activity at pH 8.0 and does not contain any subunit corresponding in size to nodulin-35. Uricase I, also present in young infected roots, declines at a time when nodulin-35 appears. Monospecific antibodies prepared against uricase II (nodulin-35) showed no cross-reactivity. Uricase II was localized in the uninfected cells of the nodule tissue. These results are consistent with the concept that a nodule-specific ureide metabolism takes place in peroxisomes of uninfected cells, and suggest the participation of uricase II in this pathway.     

Improved Heterojunction Quality in Cu2O-based Solar Cells Through the Optimization of Atmospheric Pressure Spatial Atomic Layer Deposited Zn1-xMgxO

Atmospheric pressure spatial atomic layer deposition (AP-SALD) was used to deposit n-type ZnO and Zn_1-xMg_xO thin films onto p-type thermally oxidized Cu₂O substrates outside vacuum at low temperature. The performance of photovoltaic devices featuring atmospherically fabricated ZnO/Cu₂O heterojunction was dependent on the conditions of AP-SALD film deposition, namely, the substrate temperature and deposition time, as well as on the Cu₂O substrate exposure to oxidizing agents prior to and during the ZnO deposition. Superficial Cu₂O to CuO oxidation was identified as a limiting factor to heterojunction quality due to recombination at the ZnO/Cu₂O interface. Optimization of AP-SALD conditions as well as keeping Cu₂O away from air and moisture in order to minimize Cu₂O surface oxidation led to improved device performance. A three-fold increase in the open-circuit voltage (up to 0.65 V) and a two-fold increase in the short-circuit current density produced solar cells with a record 2.2% power conversion efficiency (PCE). This PCE is the highest reported for a Zn_1-xMg_xO/Cu₂O heterojunction formed outside vacuum, which highlights atmospheric pressure spatial ALD as a promising technique for inexpensive and scalable fabrication of Cu₂O-based photovoltaics.     

Copper binding traps the folded state of the SCO protein from Bacillus subtilis

The SCO protein from the aerobic bacterium Bacillus subtilis (BsSCO) is involved in the assembly of the cytochrome c oxidase complex, and specifically with the Cu_A center. BsSCO has been proposed to play various roles in Cu_A assembly including, the direct delivery of copper ions to the Cu_A site, and/or maintaining the appropriate redox state of the cysteine ligands during formation of Cu_A. BsSCO binds copper in both Cu(II) and Cu(I) redox states, but has a million-fold higher affinity for Cu(II). As a prerequisite to kinetic studies, we measured equilibrium stability of oxidized, reduced and Cu(II)-bound BsSCO by chemical and thermal induced denaturation. Oxidized and reduced apo-BsSCO exhibit two-state behavior in both chemical- and thermal-induced unfolding. However, the Cu(II) complex of BsSCO is stable in up to nine molar urea. Thermal or guanidinium-induced unfolding of BsSCO-Cu(II) ensues only as the Cu(II) species is lost. The effect of copper (II) on the folding of BsSCO is complicated by a rapid redox reaction between copper and reduced, denatured BsSCO. When denatured apo-BsSCO is refolded in the presence of copper (II) some of the population is recovered as the BsSCO-Cu(II) complex and some is oxidized indicating that refolding and oxidation are competing processes. The proposed functional roles for BsSCO in vivo require that its cysteine residues are reduced and the presence of copper during folding may be detrimental to BsSCO attaining its functional state.     

Suppressed Deep Traps and Bandgap Fluctuations in Cu2CdSnS4 Solar Cells with ≈8% Efficiency

The identification of performance‐limiting factors is a crucial step in the development of solar cell technologies. Cu₂ZnSn(S,Se)₄‐based solar cells have shown promising power conversion efficiencies in recent years, but their performance remains inferior compared to other thin‐film solar cells. Moreover, the fundamental material characteristics that contribute to this inferior performance are unclear. In this paper, the performance‐limiting role of deep‐trap‐level‐inducing 2Cu_Zn+Sn_Zn defect clusters is revealed by comparing the defect formation energies and optoelectronic characteristics of Cu₂ZnSnS₄ and Cu₂CdSnS₄. It is shown that these deleterious defect clusters can be suppressed by substituting Zn with Cd in a Cu‐poor compositional region. The substitution of Zn with Cd also significantly reduces the bandgap fluctuations, despite the similarity in the formation energy of the Cu_Zn+Zn_Cu and Cu_Cd+Cd_Cu antisites. Detailed investigation of the Cu₂CdSnS₄ series with varying Cu/[Cd+Sn] ratios highlights the importance of Cu‐poor composition, presumably via the presence of V_Cu, in improving the optoelectronic properties of the cation‐substituted absorber. Finally, a 7.96% efficient Cu₂CdSnS₄ solar cell is demonstrated, which shows the highest efficiency among fully cation‐substituted absorbers based on Cu₂ZnSnS₄.