Influence of serum proteins on conformation of prostate-specific antigen

Partition behavior of prostate-specific antigen (PSA) was studied in aqueous Dextran-Ficoll two-phase system. It was found that the partitioning of PSA changed in the presence of other proteins, in particular, bovine serum albumin, human serum albumin, human transferrin, and human gamma-globulin. The partition coefficient of PSA in mixtures with increasing amounts of these proteins decreased along the S-shaped curve and dropped to essentially the same value at the 10(4)-10(5) protein: PSA molar ratio. Partition behavior of the above proteins was examined separately. Partition coefficient of a protein represents the protein solvent exposed residues; i.e., it reflects the 3D-structure of the protein in solution. Partition of binary protein mixtures reflects the interaction of the two proteins and therefore characterizes the PSA-induced conformational changes in a protein agent and the change in the PSA conformation induced by a protein agent. In other words, the protein effect on the partition behavior of free PSA may be explained by the effect of the non-specific PSA-protein interactions on PSA conformation. Formation of such PSA-protein encounter complexes was shown to be dominated by the electrostatic forces, since the efficiency of a given protein-agent to induce changes in the partition behavior of PSA was proportional to its absolute mean net charge. Furthermore, in agreement with the earlier hypothesis that the protein segments with increased dynamic propensities (i.e., 'discrete breathers') can be important for conformational transitions accompanying binding processes, our analysis of intrinsically disordered regions (IDR) in all the proteins examined showed that the propensity for intrinsic disorder is related to the PSA partition-modulating capability of the protein.     

Analytical partitioning of poly(ethylene glycol)-modified proteins

Covalently grafting proteins with varying numbers (n) of poly(ethylene glycol) molecules (PEGs) often enhances their biomedical and industrial usefulness. Partition between the phases in aqueous polymer two-phase systems can be used to rapidly characterize polymer-protein conjugates in a manner related to various enhancements. The logarithm of the partition coefficient (K) approximates linearity over the range 0<n<x. However, x varies with the nature of the conjugate (e.g., protein molecular mass) and such data analysis does not facilitate the comparison of varied conjugates. The known behavior of surface localized PEGs suggests a better correlation should exist between log K and the weight fraction of polymer in PEG-protein conjugates. Data from four independent studies involving three proteins (granulocyte-macrophage colony stimulation factor, bovine serum albumin and immunoglobulin G) has been found to support this hypothesis. Although somewhat simplistic, ‘weight fraction’ based analysis of partition data appears robust enough to accommodate laboratory to laboratory variation in protein, polymer and phase system type. It also facilitates comparisons between partition data involving disparate polymer-protein conjugates.     

Crystal structure of human FAF1 UBX domain reveals a novel FcisP touch-turn motif in p97/VCP-binding region

UBX domain is a general p97/VCP-binding module found in an increasing number of proteins including FAF1, p47, SAKS1 and UBXD7. FAF1, a multi-functional tumor suppressor protein, binds to the N domain of p97/VCP through its C-terminal UBX domain and thereby inhibits the proteasomal protein degradation in which p97/VCP acts as a co-chaperone. Here we report the crystal structure of human FAF1 UBX domain at 2.9 Å resolution. It reveals that the conserved FP sequence in the p97/VCP-binding region adopts a rarely observed cis-Pro touch-turn structure. We call it an FcisP touch-turn motif and suggest that it is the conserved structural element of the UBX domain. Four FAF1 UBX molecules in an asymmetric unit of the crystal show two different conformations of the FcisP touch-turn motif. The phenyl ring of F⁶¹⁹ in the motif stacks partly over cis-Pro⁶²⁰ in one conformation, whereas it is swung out from cis-P⁶²⁰, in the other conformation, and forms hydrophobic contacts with the residues of the neighboring molecule. In addition, the entire FcisP touch-turn motif is pulled out in the second conformation by about 2 Å in comparison to the first conformation. Those conformational differences observed in the p97/VCP-binding motif caused by the interaction with neighboring molecules presumably represent the conformational change of the UBX domain on its binding to the N domain of p97/VCP.     

Learning about protein folding via potential functions

Over the last few years we have developed an empirical potential function that solves the protein structure recognition problem: given the sequence for an n-residue globular protein and a collection of plausible protein conformations, including the native conformation for that sequence, identify the correct, native conformation. Having determined this potential on the basis of only some 6500 native/nonnative pairs of structures for 58 proteins, we find it recognizes the native conformation for essentially all compact, soluble, globular proteins having known native conformations in comparisons with 10⁴ to 10⁶ reasonable alternative conformations apiece. In this sense, the potential encodes nearly all the essential features of globular protein conformational preference. In addition it “knows” about many additional factors in protein folding, such as the stabilization of multimeric proteins, quaternary structure, the role of disulfide bridges and ligands, proproteins vs. processed proteins, and minimal strand lengths in globular proteins. Comparisons are made with other sorts of protein folding problems, and applications in protein conformational determination and prediction are discussed. © 1994 Wiley-Liss, Inc.     

Partial purification of penicillin acylase from Escherichia coli in poly(ethylene glycol)–sodium citrate aqueous two-phase systems

Studies on the partition and purification of penicillin acylase from Escherichia coli osmotic shock extract were performed in poly(ethylene glycol)–sodium citrate systems. Partition coefficient behavior of the enzyme and total protein are similar to those described in other reports, increasing with pH and tie line length and decreasing with PEG molecular weight. However, some selectivity could be attained with PEG 1000 systems and long tie line at pH 6.9. Under these conditions 2.6-fold purification with 83% yield were achieved. Influence of pH on partition shows that is the composition of the system and not the net charge of the enzyme that determines the behaviour in these conditions. Addition of NaCl to PEG 3350 systems significantly increases the partition of the enzyme. Although protein partition also increased, purification conditions were possible with 1.5 M NaCl where 5.7-fold purification and 85% yield was obtained. This was possible due to the higher hydrophobicity of the enzyme compared to that of most contaminants proteins.     

Characterization of centchroman binding protein in plasma of rhesus monkey (Macaca mulatta)

Centchroman, a nonsteroidal antifertility agent was studied for its binding to monkey (Macaca mulatta) plasma proteins using charcoal adsorption and electrophoretic techniques. ¹⁴C-centchroman showed a low affinity binding and did not compete for ³H-cortisol or ³H-DHT binding sites in plasma. ¹⁴C-centchroman binding protein was heat stable in nature and showed the electrophoretic pattern similar to that of albumin (Rf 0.70). Thus centchroman binds to albumin in monkey plasma which can be suggested as carrier protein for this contraceptive agent.     

Protein H — a surface protein of Streptococcus pyogenes with separate binding sites for lgG and albumin

Protein H, a molecule expressed at the surface of some strains of Streptococcus pyogenes, has affinity for the constant (lgGFc) region of immunoglobulin (lg) G. In absorption experiments with human plasma, protein H–sepharose could absorb not only lgG but also albumin from plasma. The affinity constant for the reaction between albumin and protein H was 7.8 × 10⁹M⁻¹, which is higher than the affinity between lgG and protein H (K_a= 1.6 × 10⁹ M⁻¹). Fragments of protein H were generated with deletion plasmids and polymerase chain reaction (PCR) technology. Using these fragments in various protein–protein interaction assays, the binding of albumin was mapped to three repeats (C1–C3) in the C-terminal half of protein H. On the albumin molecule, the binding site for protein H was found to overlap the site for protein G, another albumin- and lgGFc-binding bacterial surface protein. Aiso lgGFc-binding could be mapped with the protein H fragments and the region was found N-terminally of the C repeats. A synthetic peptide (25 amino acid residues long) based on a sequence in this region was shown to inhibit the binding of protein H to immobilized lgG or lgGFc. This sequence was not found in previously described lgGFc-binding proteins. However, two other cell surface proteins of S. pyogenes exhibited highly homologous regions. The results identify lgGFc- and albumin binding regions of protein H and further define and emphasize the convergent evolution among bacterial surface proteins interacting with human plasma proteins.     

Studies on 125I-labeled proteins in rat plasma using an air-driven ultracentrifuge: protein-protein interactions and nonideality

The molecular weights of a number of ¹²⁵I-labeled plasma proteins have been determined from an analysis of their sedimentation equilibrium behavior in an air-driven ultracentrifuge. The values obtained agree well with results obtained by other methods. Molecular weights obtained for ¹²⁵I-labeled bovine serum albumin and the rat serum proteins albumin, α₁-acid glycoprotein, and major acute-phase α₁-protein were unaffected by the addition of 7% rat plasma. Direct evidence for protein-protein interactions was obtained for mixtures of ¹²⁵I-labeled rat α₁-acid glycoprotein and the plant lectin concanavalin A and for mixtures of ¹²⁵I-labeled protein A from Staphylococcus aureus and 7% rat plasma. Interactions of a different type were observed when the sedimentation equilibrium profiles of ¹²⁵I-labeled proteins were determined in concentrated solutions of other proteins. Under these conditions the effects of molecular exclusion or nonideality became significant and low estimates were obtained for the molecular weights of the labeled proteins. Analysis of the data obtained for ¹²⁵I-labeled bovine serum albumin in concentrated solutions of bovine serum albumin (20–80 mg/ ml) yielded nonideality coefficients in good agreement with literature values. Analysis of the behavior of ¹²⁵I-labeled rat serum albumin, transferrin, and α₁-acid glycoprotein yielded nonideality coefficients and hence activities of these proteins in undiluted rat plasma.     

Conformational States of the Water-Soluble Fragment of Cytochrome b5. I. pH-Induced Denaturation

Cytochrome b ₅ is a membrane protein that comprises two fragments: one is water-soluble and heme-containing, and the other is hydrophobic and membrane-embedded. The function of electron transfer is performed by the former whose crystal structure is known; however, its conformational states when in the membrane field and interacting with other proteins are still to be studied. Previously, we proposed water–alcohol mixtures for modeling the effect of membrane surface on proteins, and used this approach to study the conformational behavior of positively charged cytochrome c as well as relatively neutral retinol-binding protein also functioning in the field of a negatively charged membrane. The current study describes the conformational behavior of the negatively charged water-soluble fragment of cytochrome b ₅ as dependent on pH. Decreasing pH was shown to transform the fragment state from native to intermediate, similar to the molten globule reported earlier for other proteins in aqueous solutions: at pH 3.0, the fragment preserved a pronounced secondary structure and compactness but lost its rigid tertiary structure. A possible role of this intermediate state in cytochrome b ₅ functioning is discussed.     

Folic acid delivery by serum proteins: loading efficacy and protein morphology

The loading efficacy of folic acid with serum proteins human serum albumin (HSA), bovine serum albumin (BSA), and beta-lactoglobulin (β-LG) was analyzed and the effect of acid conjugation on protein morphology was determined. Structural analysis showed that folic acid binds HSA, BSA, and β-LG via hydrophilic, hydrophobic, and H-bonding contacts with BSA forming more stable conjugates than HSA and β-LG. Molecular modeling showed the presence of several H-bonding systems, stabilizing acid–protein conjugates. Folic acid conjugation alters protein conformation by major alterations of α-helix and β-sheet. TEM images showed major protein morphological changes inducing protein aggregation upon acid interaction. The results show that serum proteins can deliver folic acid to target molecules.     

Diffusion of bovine serum albumin in a neutral polymer solution

The diffusion coefficient D of bovine serum albumin through various solutions (pH 7.0, 0.5M NaCl) of polythylene oxide (M_w ～ 1 × 10⁵, 3 × 10⁵) was studied with quasielastic light scattering. In solutions of the 1 × 10⁵ polymer solution at polymer concentrations above 0.5 g/L, D is considerably greater than would have been expected from the viscosity of water:polymer mixtures, the deviations being larger at low protein concentration that at high protein concentration. With either polymer, D falls with increasing protein concentration.     

Interaction of Bovine β-Lactoglobulin and Other Bovine and Human Whey Proteins with Retinol and Fatty Acids

The interaction of bovine and human whey proteins with retinol and palmitic acid has been studied. Using gel filtration it was found that bovine β-lactoglobulin and α-lactalbumin and serum albumin from both species bind retinol in vitro while the ability to bind palmitic acid is restricted to bovine β-lactoglobulin and bovine and human serum albumin. Using equilibrium dialysis, β-lactoglobulin was found to display two binding sites for retinol per dimeric molecule with an association constant of 1.5 × 10⁴m^-1. Competition experiments showed that when the concentration ratio between total fatty acids and retinol is similar to that found in milk, palmitic acid competes with the binding of retinol to β-lactoglobulin.     

Optimization of bovine serum albumin partition coefficient in aqueous two-phase systems

Partitioning of proteins in aqueous two-phase systems has been shown to provide a powerful method for separating and purifying mixtures of biomolecules by extraction. These systems are composed of aqueous solutions of either two water-soluble polymers, usually polyethylene glycol (PEG) and dextran (Dx), or a polymer and a salt, usually PEG and phosphate or sulfate. There are many factors which influence the partition coefficient K, the ratio of biomolecule concentration in the top phase to that in the bottom phase, in aqueous two-phase systems. The value of the partition coefficient relies on the physico-chemical properties of the target biomolecule and other molecules and their interactions with those of the chosen system. In this work, the partition behavior of pure bovine serum albumin in aqueous two-phase systems was investigated in order to see the effects of changes in phase properties on the partition coefficient K. The concentration of NaCl and pH were considered to be the factors having influence on K. Optimal conditions of these factors were obtained using the Box-Wilson experimental design. The optimum value of K was found as 0.0126 when NaCl concentration and pH were 0.14 M and 9.8, respectively, for a phase system composed of 8% (w/w) polyethylene glycol 3,350 - 9 (% w/w) dextran 37,500 - 0.05 M phosphate at 20 °C.     

Polyethyleneglycol molecular mass and polydispersivity effect on protein partitioning in aqueous two-phase systems

The partitioning of model proteins (bovine serum albumin, ovalbumin, trypsin and lysozyme) was assayed in aqueous two-phase systems formed by a salt (potassium phosphate, sodium sulfate and ammonium sulfate) and a mixture of two polyethyleneglycols of different molecular mass. The ratio between the PEG masses in the mixtures was changed in order to obtain different polymer average molecular mass. The effect of polymer molecular mass and polydispersivity on the protein partition coefficient was studied. The relationship between the logarithm of the protein partition coefficient and the average molecular mass of the phase-forming polymer was found to depend on the polyethyleneglycol molecular mass, the salt type in the bottom phase and the molecular weight of the partitioned protein. The polymer polydispersivity proved to be a very useful tool to increase the separation between two proteins having similar isoelectrical point.     

A comparative study on intrinsic fluorescence of BSA and lysozyme proteins in presence of different divalent ions from their solution and thin film conformations

Optical emission behaviours of lysozyme and bovine serum albumin, from bulk and thin film geometry, were studied in the presence of three different divalent ions (Mg²⁺, Ca²⁺ or Ba²⁺) using different spectroscopic [steady‐state fluorescence, UV–Vis and Fourier transform infra‐red (FTIR)] techniques. Additionally, protein thin films on silicon surfaces were prepared and morphological studies were carried out using atomic force microscopy. Dynamic quenching was mainly identified for both proteins in the presence of Mg²⁺, Ca²⁺ and Ba²⁺ ions. The molecular conformation of the proteins was modified in thin films compared with that in solution, consequently quenching efficiencies also varied. ATR‐FTIR studies confirmed the conformational changes of proteins in the presence of all divalent ions. All metal ions used were divalent in nature and belonged to the same group of the periodic table but, depending on their individual characteristics such as electron affinity, ionic radius, etc., the magnitude of the protein and hydrated ion interaction varied and accordingly the quenching efficiency was modified. Quenching was maximum for Ca²⁺ ions, followed by the other two ions. Our study clearly illustrates the geometry‐dependent physical and biological functions of proteins.     

Photo-induced riboflavin binding to the tryptophan residues of bovine and human serum albumins

Summary The photobinding between riboflavin and the Trp residues from human and bovine serum albumins at two pH-dependent protein conformations was studied. At pH 7.0 both proteins showed photo-adduct formation with hyperbolic kinetics. In the bovine serum albumin this is attributed to the different locations of the two Trp residues. In the case of the human serum albumin, which has only one Trp residue, this behaviour may be related to different molecular conformations of the protein, as is also manifest in the iodide quenching experiments. At pH 3.5, the kinetics of the photo-adduct formation were found to be slower and showed a monophasic behaviour. These results are due to the conformational change of these proteins at acidic pH; the Trp residues of both proteins being now located in a more hydrophobic environment. When bovine serum albumin was anaerobically irradiated at pH 7.0 in the presence of¹⁴C-riboflavin and then cleaved by CNBr, two peptides were obtained, containing the Trp-134 and Trp-212 residues, respectively. The incorporation of¹⁴C-riboflavin in these samples was significantly higher at the level of the peptide containing the Trp-134 residue. Furthermore, it was demonstrated, that the energy transfer from enzymatically generated triplet acetone to riboflavin can also promote the binding of this vitamin to the Trp residues of human and bovine serum albumins.     

Metabolic interactions between animal cells through permeable intercellular junctions.

The isolated perfused rat liver was used to study the degradation of ¹²⁵I-labelled protein supplied in the perfusion medium. Formaldehyde-denatured proteins (human serum albumin, bovine serum albumin and especially rat liver phosphoenolpyruvate carboxykinase (GTP)) were taken up by the liver and degraded at high rates. Native human serum albumin was not degraded at significant rates by the perfused liver, while native phosphoenolpyruvate carboxykinase (GTP) was catabolised at about one-fourth the rate of the denatured enzyme. The degradation rate of denatured human serum albumin increased markedly as protein was added up to 0.7 mg, and more gradually with further increases in added protein. The biphasic nature of concentration dependence probably reflects the contribution of different cell types in the liver. Autoradiographic examination of serial biopsies taken during perfusion of the liver with formaldehyde-denatured, ¹²⁵I-labelled bovine serum albumin showed that at the cellular level the radioactivity was located predominantly in Kupffer and other non-parenchymal cells; and at the subcellular level the radioactivity was largely in endocytic vesicles, lysosomes and occasionally in the sinusoidal spaces. No significant radioactivity was found associated with other cytoplasmic organelles or the nucleus. It is concluded that lysosomes of the non-parenchymal cells are primarily responsible for the degradation of denatured extracellular protein that enters the liver.     

Loss of intramolecular electrostatic interactions and limited conformational ensemble may promote self‐association of cis–tau peptide

Self‐association of proteins can be triggered by a change in the distribution of the conformational ensemble. Posttranslational modification, such as phosphorylation, can induce a shift in the ensemble of conformations. In the brain of Alzheimer's disease patients, the formation of intra‐cellular neurofibrillary tangles deposition is a result of self‐aggregation of hyper‐phosphorylated tau protein. Biochemical and NMR studies suggest that the cis peptidyl prolyl conformation of a phosphorylated threonine‐proline motif in the tau protein renders tau more prone to aggregation than the trans isomer. However, little is known about the role of peptidyl prolyl cis/trans isomerization in tau aggregation. Here, we show that intra‐molecular electrostatic interactions are better formed in the trans isomer. We explore the conformational landscape of the tau segment containing the phosphorylated‐Thr²³¹‐Pro²³² motif using accelerated molecular dynamics and show that intra‐molecular electrostatic interactions are coupled to the isomeric state of the peptidyl prolyl bond. Our results suggest that the loss of intra‐molecular interactions and the more restricted conformational ensemble of the cis isomer could favor self‐aggregation. The results are consistent with experiments, providing valuable complementary atomistic insights and a hypothetical model for isomer specific aggregation of the tau protein. Proteins 2015; 83:436–444. © 2014 Wiley Periodicals, Inc.