Cooperativity and site selectivity in the ileal lipid binding protein.

The ileal lipid binding protein (ILBP or I-BABP) binds bile salts with positive cooperativity and has unusual site selectivity, whereby cholic acid binds preferentially in one site and chenodeoxycholic in another, despite both sites having an affinity for both ligands and the ligands only differing by a single hydroxyl group. Previous studies of the human variant have assumed that the ligand/protein binding ratio is 2:1, but we show, using electrospray ionization mass spectroscopy, that human ILBP binds bile acids with a 3:1 ratio, even at low protein and ligand concentrations. Docking calculations and molecular dynamics (MD) simulations identify an allosterically active binding site on the protein exterior that induces a change from a closed conformation to an open one, characterized by a movement of one of the α-helices by ~10° with respect to the ß-clam shell. Additional independent MD simulations of several hundred nanoseconds implicate the change between conformations in the mechanisms of both cooperativity and ligand site selectivity.

The role of tryptophan in staphylococcal nuclease stability.

Staphylococcal nuclease (SNase) has a single Trp residue at position 140. Circular dichroism, intrinsic and ANS-binding fluorescence, chemical titrations and enzymatic assays were used to measure the changes of its structure, stability and activities as the Trp was mutated or replaced to other positions. The results show that W140 is critical to SNase structure, stability, and function. Mutants such as W140A, F61W/W140A, and Y93W/W140A have unfolding, corrupted secondary and tertiary structures, diminished structural stability and attenuated catalytic activity as compared to the wild type. The deleterious effects of W140 substitution cannot be compensated by concurrent changes at topographical locations of position 61 or 93. Local hydrophobicity defined as a sum of hydrophobicity around a given residue within a distance is found to be a relevant property to SNase folding and stability.

Structure and function of a custom anticancer peptide, CB1a.

Several natural antimicrobial peptides including cecropins, magainins and melittins have been found to kill cancer cells. However, their efficacy may not be adequate for their development as anticancer agents. In this study, we used a natural antimicrobial peptide, cecropin B (CB), as a template to generate a novel anticancer peptide. Cecropin B is an amphipathic and polycationic peptide derived from the hemolymph of Hyalophora cecropia with well-known antimicrobial and cytolytic properties. The signature pattern of cecropins is W-x-(0,2)-[KDN]-x-{L}-K-[KRE]-[LI]-E-[RKN] (PROSITE: PS00268), and this signature sequence is located at N-terminus of CB. CB1a was constructed by repeating the N-terminal ten amino acids of CB three times and including a hinge near C-terminus. The circular dichroism spectra showed that CB1a is unstructured in aqueous solution, but adopt a helical conformation in membrane-like environment. The solution structure of CB1a in a polar solvent was also studied by NMR. CB1a formed a helix-hinge-helix in 20% HFIP solution, and it was found the bent angle between two helical segments was induced ranging from 60 degrees to 110 degrees . A heparin-binding motif is located in the central part of helix 1. Isothermal titration calorimetry reveals the association constant of CB1a bound to low molecular weight heparin is 1.66 x 10(5)M(-1) at physiological ionic strength at 25 degrees C. Binding of CB1a to heparin produces a large conformational change toward a more structural state. CB1a demonstrated promising activity against several cancer cells but low toxicity against non-cancer cells. The IC(50) of CB1a on leukemia and stomach carcinoma cells were in the range of 2-8-fold lower than those of CB. Besides, CB1a exhibited low hemolytic activity against human red blood cells. Due to these properties, CB1a has the potential to become a promising anticancer agent.

Thermostability of the N-terminal RNA-binding domain of the SARS-CoV nucleocapsid protein: experiments and numerical simulations.

Differential scanning calorimetry, circular dichroism spectroscopy, nuclear magnetic resonance spectroscopy, and numerical simulations were used to study the thermostability of the N-terminal RNA-binding domain (RBD) of the SARS-CoV nucleocapsid protein. The transition temperature of the RBD in a mixing buffer, composed of glycine, sodium acetate, and sodium phosphate with 100 mM sodium chloride, at pH 6.8, determined by differential scanning calorimetry and circular dichroism, is 48.74 degrees C. Experimental results showed that the thermal-induced unfolding-folding transition of the RBD follows a two-state model with a reversibility >90%. Using a simple Go-like model and Langevin dynamics we have shown that, in agreement with our experiments, the folding of the RBD is two-state. Theoretical estimates of thermodynamic quantities are in reasonable agreement with the experiments. Folding and thermal unfolding pathways of the RBD also were experimentally and numerically studied in detail. It was shown that the strand beta(1) from the N-terminal folds last and unfolds first, while the remaining beta-strands fold/unfold cooperatively.

Compact dimension of denatured states of staphylococcal nuclease.

Fluorescence and circular dichroism stopped-flow have been widely used to determine the kinetics of protein folding including folding rates and possible folding pathways. Yet, these measurements are not able to provide spatial information of protein folding/unfolding. Especially, conformations of denatured states cannot be elaborated in detail. In this study, we apply the method of fluorescence energy transfer with a stopped-flow technique to study global structural changes of the staphylococcal nuclease (SNase) mutant K45C, where lysine 45 is replaced by cysteine, during folding and unfolding. By labeling the thiol group of cysteine with TNB (5,5'-dithiobis-2-nitrobenzoic acid) as an energy acceptor and the tryptophan at position 140 as a donor, distance changes between the acceptor and the donor during folding and unfolding are measured from the efficiency of energy transfer. Results indicate that the denatured states of SNase are highly compact regardless of how the denatured states (pH-induced or GdmCl-induced) are induced. The range of distance changes between two probes is between 25.6 and 25.4 A while it is 20.4 A for the native state. Furthermore, the folding process consists of three kinetic phases while the unfolding process is a single phase. These observations agree with our previous sequential model: N(0) left arrow over right arrow D(1) left arrow over right arrow D(2) left arrow over right arrow D(3) (Chen et al., J Mol Biol 1991;220:771-778). The efficiency of protein folding may be attributed to initiating the folding process from these compact denatured structures.

Local stability identification and the role of a key aromatic amino acid residue in staphylococcal nuclease refolding.

Staphylococcal nuclease (SNase) is a model protein that contains one domain and no disulfide bonds. Its stability in the native state may be maintained mainly by key amino acids. In this study, two point-mutated proteins each with a single base substitution [alanine for tryptophan (W140A) and alanine for lysine (K133A)] and two truncated fragment proteins (positions 1-139 [SNase(1-139) or W140O] and positions 1-141 [SNase(1-141) or E142O]) were generated. Differential scanning microcalorimetry in thermal denaturation experiments showed that K133A and E142O have nearly unchanged DeltaH(cal) relative to the wild-type, whereas W140A and W140O display zero enthalpy change (DeltaH(cal) approximately 0). Far-UV CD measurements indicate secondary structure in W140A but not W140O, and near-UV CD measurements indicate no tertiary structure in either W140 mutant. These observations indicate an unusually large contribution of W140 to the stability and structural integrity of SNase.

Local stability identification and the role of key acidic amino acid residues in staphylococcal nuclease unfolding.

Staphylococcal nuclease is a single domain protein with 149 amino acids. It has no disulfide bonds, which makes it a simple model for the study of protein folding. In this study, 20 mutants of this protein were generated each with a single base substitution of glycine for negatively charged glutamic acid or aspartic acid. Using differential scanning microcalorimetry in thermal denaturation experiments, we identified two mutants, E75G and E129G, having approximately 43% and 44%, respectively, lower DeltaH(cal) values than the wild-type protein. Furthermore, two mutants, E75Q and E129Q, were created and the results imply that substitution of the Gly residue has little influence on destabilization of the secondary structure that leads to the large perturbation of the tertiary protein structure stability. Two local stable areas formed by the charge-charge interactions around E75 and E129 with particular positively charged amino acids are thus identified as being significant in maintenance of the three-dimensional structure of the protein.