Project description:The interactions of luteolin (Lut) with bovine serum albumin (BSA) mediated by Cu(II) were investigated by spectroscopic, calorimetric, and molecular dynamic (MD) methods. Fluorescence studies showed that the binding of Lut to BSA was significantly enhanced by Cu(II) coordination with the number of binding sites and binding constant increasing from n = 1 and K a = 3.2 × 105 L·mol-1 for Lut to n = 2 and K a = 7.1 × 105 L·mol-1 for a 1:1 Cu(II)-luteolin complex, in agreement with the results from isothermal titration calorimetry (ITC). Site-specific experiments with warfarin and ibuprofen and MD confirmed that two binding sites of BSA were sequentially occupied by two Cu(II)-luteolin complexes. Cu(II) coordination increased the antioxidant activity of luteolin by 60% in the inhibition of carbonyl formation from the oxidation of amino groups in the side chain of BSA induced by the peroxyl radical ROO•; however, it counteracted the antioxidant effects of luteolin and played pro-oxidative roles in BSA aggregation induced by •OH.

Project description:Copper(II) complexes of thiosemicarbazones (TSCs) often exhibit anticancer properties, and their pharmacokinetic behavior can be affected by their interaction with blood transport proteins. Interaction of copper(II) complexes of an {N,N,S} donor α-N-pyridyl TSC (Triapine) and an {O,N,S} donor 2-hydroxybenzaldehyde TSC (STSC) with human serum albumin (HSA) was investigated by UV-visible and electron paramagnetic resonance spectroscopy at physiological pH. Asp-Ala-His-Lys and the monodentate N-methylimidazole were also applied as binding models. Conditional formation constants were determined for the ternary copper(II)-TSC complexes formed with HSA, DAHK, and N-methylimidazole based on the spectral changes of both charge transfer and d-d bands. The neutral N-methylimidazole displays a similar binding affinity to both TSC complexes. The partially negatively charged tetrapeptide binds stronger to the positively charged Triapine complex in comparison to the neutral STSC complex, while the opposite trend was observed for HSA, which demonstrates the limitations of the use of simple ligands to model the protein binding. The studied TSC complexes are able to bind to HSA in a fast process, and the conditional constants suggest that their binding strength is only weak-to-moderate.

Project description:Human serum albumin (HSA) is the most abundant plasma protein, which functions to transport a large range of ligands within the circulation. These interactions have important implications for human health and disease. The primary binding site for CuII ions on HSA is known to be the so-called amino-terminal CuII and NiII binding (ATCUN) motif. However, the number and identity of secondary binding sites is currently not understood. In this study, we harnessed a suite of contemporary electron paramagnetic resonance (EPR) spectroscopy methods to investigate recombinantly produced constructs of HSA bearing single-histidine knockouts, with the aim to characterise its endogenous CuII ion binding sites.

Project description:Hepcidin is a peptide hormone that regulates the homeostasis of iron metabolism. The N-terminal domain of hepcidin is conserved amongst a range of species and is capable of binding Cu(II) and Ni(II) through the amino terminal copper-nickel binding motif (ATCUN). It has been suggested that the binding of copper to hepcidin may have biological relevance. In this study we have investigated the binding of Cu(II) with model peptides containing the ATCUN motif, fluorescently labelled hepcidin and hepcidin using MALDI-TOF mass spectrometry. As with albumin, it was found that tetrapeptide models of hepcidin possessed a higher affinity for Cu(II) than that of native hepcidin. The log K 1 value of hepcidin for Cu(II) was determined as 7.7. Cu(II) binds to albumin more tightly than hepcidin (log K 1 = 12) and in view of the serum concentration difference of albumin and hepcidin, the bulk of kinetically labile Cu(II) present in blood will be bound to albumin. It is estimated that the concentration of Cu(II)-hepcidin will be less than one femtomolar in normal serum and thus the binding of copper to hepcidin is unlikely to play a role in iron homeostasis. As with albumin, small tri and tetra peptides are poor models for the metal binding properties of hepcidin.

Project description:We have investigated the Cu(II)- and Ni(II)-binding properties of chicken serum albumin (CSA) and of the native sequence tripeptide derived from the N-terminus of this protein. Spectrophotometric and equilibrium dialysis experiments demonstrate that Cu(II) and Ni(II) bind non-specifically at the N-terminus of CSA. Proton displacement studies show that the histidine residue in the fourth position of the protein does not appear to participate in the binding of the two metals. Consistent results were obtained with the native sequence tripeptide L-aspartyl-L-alanyl-L-glutamic acid N-methylamide. The results presented here demonstrate that neither the glutamic acid residue in the third position nor the histidine in the fourth position participate in the binding of Cu(II) and Ni(II) to CSA. It is known, however, that a number of other albumins with a histidine residue in the third position possess high-affinity Cu(II)- and Ni(II)-binding sites. Our results provide further evidence that the N-terminal Cu(II)/Ni(II)-binding motif requires a histidine at the third position in order to bind Cu(II) and Ni(II) specifically.

Project description:The negative environmental and social impacts of food waste accumulation can be mitigated by utilizing bio-refineries' approach where food waste is revalorized into high-value products, such as prodigiosin (PG), using microbial bioprocesses. The diverse biological activities of PG position it as a promising compound, but its high production cost and promiscuous bioactivity hinder its wide application. Metal ions can modulate the electronic properties of organic molecules, leading to novel mechanisms of action and increased target potency, while metal complex formation can improve the stability, solubility and bioavailability of the parent compound. The objectives of this study were optimizing PG production through bacterial fermentation using food waste, allowing good quantities of the pure natural product for further synthesizing and evaluating copper(II) and zinc(II) complexes with it. Their antimicrobial and anticancer activities were assessed, and their binding affinity toward biologically important molecules, bovine serum albumin (BSA) and DNA was investigated by fluorescence emission spectroscopy and molecular docking. The yield of 83.1 mg/L of pure PG was obtained when processed meat waste at 18 g/L was utilized as the sole fermentation substrate. The obtained complexes CuPG and ZnPG showed high binding affinity towards target site III of BSA, and molecular docking simulations highlighted the affinity of the compounds for DNA minor grooves.

Project description:The peptide Asp-Ala-His-NH-Me was subjected to removal of its N-terminal residue by transamination and scission. Despite the high affinity of the peptide for Cu2+ ions, they catalysed its transamination smoothly. Two main transamination products were found, a complication previously observed with another peptide with an N-terminal aspartic residue, but their scission gave a single product, Ala-His-NH-Me. This was subjected to a further cycle of transamination and scission, and gave a single product after each step. For scission of transaminated peptides it proved unnecessary to remove them from transamination reagents provided that transamination was stopped with EDTA before adding the scission reagent.

Project description:Detailed studies are reported on the Ni(II)-binding site of human serum albumin (HSA) and the results are compared with those obtained from the N-terminal native-sequence peptide, l-aspartyl-l-alanyl-l-histidine N-methylamide (Asp-Ala-His-NHMe). Equilibrium dialysis of HSA and Ni(II) in 0.1m-N-ethylmorpholine/HCl buffer, pH 7.53, demonstrates a specific Ni(II)-binding site on the protein. l-Histidine, the low-molecular-weight Ni(II)-binding constituent of human serum, is shown to have a greater affinity for Ni(II) than does HSA. A small but significant amount of ternary complex HSA-Ni(II)-l-histidine is also present in the equilibrium mixture containing the three components. The log (association constant) values for the binary and ternary Ni(II) complexes are 9.57 and 16.23 respectively. The complex equilibria between Asp-Ala-His-NHMe and Ni(II) have been investigated by analytical potentiometry in aqueous solution (0.15m-NaCl, 25 degrees C). Several species, including MA, MA(2), MH(-2)A, and MH(-1)A(2) [where M and A represent Ni(II) ion and anionic peptide respectively], were detected in the system, MH(-2)A being the major complex species. Equilibrium studies involving Asp-Ala-His-NHMe, Ni(II) and l-histidine reveal the presence of a ternary complex MH(-1)AB (where B represents anionic l-histidine) at physiological pH. Detailed studies of visible-absorption spectra of HSA in the presence of Cu(II) and Ni(II) reveal that the two metal ions bind HSA at the same site. The visible-absorption spectrum of Ni(II)-HSA complex shows a highly absorbing peak at 420nm (epsilon(max.) = 137; with shoulder at 450-480nm) characteristic of a square planar or square pyramidal co-ordination arrangement about the metal ion. Similar visible-absorption characteristics were observed for the major species MH(-2)A in the Asp-Ala-His-NHMe-Ni(II) system (lambda(max.) = 420nm; epsilon(max.) = 135; with shoulder at 450-480nm). The combination of experimental results from the protein studies and the peptide analyses provides strong evidence for the structure of the Ni(II)-binding site of HSA as one that involves the alpha-amino nitrogen atom, two deprotonated peptide nitrogen atoms, the imidazole nitrogen atom and the side-chain carboxy group of the aspartic acid residue. On the basis of the results obtained from the individual ternary systems involving protein and peptide, a mechanism for the transportation of Ni(II) in the serum is proposed.

Project description:Herein we firstly reported a simple, environment-friendly, controllable synthetic method of CuSe nanosnakes at room temperature using copper salts and sodium selenosulfate as the reactants, and bovine serum albumin (BSA) as foaming agent. As the amounts of selenide ions (Se2-) released from Na2SeSO3 in the solution increased, the cubic and snake-like CuSe nanostructures were formed gradually, the cubic nanostructures were captured by the CuSe nanosnakes, the CuSe nanosnakes grew wider and longer as the reaction time increased. Finally, the cubic CuSe nanostructures were completely replaced by BSA-CuSe nanosnakes. The prepared BSA-CuSe nanosnakes exhibited enhanced biocompatibility than the CuSe nanocrystals, which highly suggest that as-prepared BSA-CuSe nanosnakes have great potentials in applications such as biomedical engineering.

Project description:Nitro-fatty acids modulate inflammatory and metabolic stress responses, thus displaying potential as new drug candidates. Herein, we evaluate the redox behavior of nitro-oleic acid (NO2-OA) and its ability to bind to the fatty acid transporter human serum albumin (HSA). The nitro group of NO2-OA underwent electrochemical reduction at -0.75 V at pH 7.4 in an aqueous milieu. Based on observations of the R-NO2 reduction process, the stability and reactivity of NO2-OA was measured in comparison to oleic acid (OA) as the negative control. These electrochemically-based results were reinforced by computational quantum mechanical modeling. DFT calculations indicated that both the C9-NO2 and C10-NO2 positional isomers of NO2-OA occurred in two conformers with different internal angles (69° and 110°) between the methyl- and carboxylate termini. Both NO2-OA positional isomers have LUMO energies of around -0.7 eV, affirming the electrophilic properties of fatty acid nitroalkenes. In addition, the binding of NO2-OA and OA with HSA revealed a molar ratio of ~7:1 [NO2-OA]:[HSA]. These binding experiments were performed using both an electrocatalytic approach and electron paramagnetic resonance (EPR) spectroscopy using 16-doxyl stearic acid. Using a Fe(DTCS)2 spin-trap, EPR studies also showed that the release of the nitro moiety of NO2-OA resulted in the formation of nitric oxide radical. Finally, the interaction of NO2-OA with HSA was monitored via Tyr and Trp residue electro-oxidation. The results indicate that not only non-covalent binding but also NO2-OA-HSA adduction mechanisms should be taken into consideration. This study of the redox properties of NO2-OA is applicable to the characterization of other electrophilic mediators of biological and pharmacological relevance.