The eukaryotic leading and lagging strand DNA polymerases are loaded onto primer-ends via separate mechanisms but have comparable processivity in the presence of PCNA.

Saccharomyces cerevisiae DNA polymerase delta (Pol delta) and DNA polymerase epsilon (Pol epsilon) are replicative DNA polymerases at the replication fork. Both enzymes are stimulated by PCNA, although to different levels. To understand why and to explore the interaction with PCNA, we compared Pol delta and Pol epsilon in physical interactions with PCNA and nucleic acids (with or without RPA), and in functional assays measuring activity and processivity. Using surface plasmon resonance technique, we show that Pol epsilon has a high affinity for DNA, but a low affinity for PCNA. In contrast, Pol delta has a low affinity for DNA and a high affinity for PCNA. The true processivity of Pol delta and Pol epsilon was measured for the first time in the presence of RPA, PCNA and RFC on single-stranded DNA. Remarkably, in the presence of PCNA, the processivity of Pol delta and Pol epsilon on RPA-coated DNA is comparable. Finally, more PCNA molecules were found on the template after it was replicated by Pol epsilon when compared to Pol delta. We conclude that Pol epsilon and Pol delta exhibit comparable processivity, but are loaded on the primer-end via different mechanisms.

Functional characteristics of the novel, human-derived recombinant FVIII protein product, human-cl rhFVIII.

INTRODUCTION: Hemophilia A is routinely treated by administration of exogenous coagulation factor VIII (FVIII). As safety and efficacy of FVIII products have improved over the years, development of FVIII-neutralizing antibodies (FVIII inhibitors) has emerged as the most serious complication. The new human cell line-derived recombinant human FVIII (human-cl rhFVIII) is the first recombinant FVIII product produced in a human cell line without additive animal proteins, with a goal of minimizing the risk of inhibitor development. MATERIALS AND METHODS: Biochemical analyzes of purity, molecular and functional attributes of the novel human-cl rhFVIII were undertaken for product characterization. RESULTS AND CONCLUSIONS: Human-cl rhFVIII was shown to be highly pure, with host-cell protein and DNA traces comparable to, or lower than, currently marketed recombinant FVIII (rFVIII) products. Human-cl rhFVIII was shown to have high specific FVIII activity and characteristics similar to full-length rFVIII products. Furthermore, no significant discrepancy between one-stage and chromogenic assay results were observed for human-cl rhFVIII, indicating potency ratios of these assays comparable to the full-length rFVIII products. In functional tests, human-cl rhFVIII exhibited physiological thrombin generation and a normal rate of inactivation by activated protein C. Importantly, human-cl rhFVIII displayed higher binding capacity with von Willebrand factor than comparator products, thus minimizing circulating unbound FVIII and further reducing the potential risk of inhibitor development.

Studies of small molecule interactions with protein phosphatases using biosensor technology.

Reversible protein phosphorylation of serine, threonine, and tyrosine residues by protein kinases and phosphatases is important for the regulation of cellular signal transduction and controls many cellular functions. Disturbances in this regulation have been implicated in a growing number of diseases, making kinases and phosphatases useful targets for therapeutic intervention. The suitability of surface plasmon resonance (SPR) technology has been widely demonstrated in many drug discovery applications. A novel and straightforward methodology is presented for analyzing small molecule binding to two serine/threonine phosphatases, PP1 and PP2B (calcineurin), and to the prototypic tyrosine phosphatase, PTP1B. Emphasis was placed on investigating the immobilization conditions of the phosphatases by using reducing conditions, inhibitors and metal ions. A comparison of inhibitor binding, either to phosphatase (PP2B) alone or in complex with the regulatory protein subunit calmodulin, revealed different kinetics. The methodology was also used to test inhibitor specificity toward different phosphatases. Inhibition of regulatory protein PP-inhibitor-2 binding to PP1 by a small molecule inhibitor was demonstrated. This type of information, together with data on compound binding that is independent of enzyme activity and in which affinities are resolved into kinetic rate constants, may be of great significance for the development of highly specific and high-affinity phosphatase inhibitors.

Structure-activity relationships of galabioside derivatives as inhibitors of E. coli and S. suis adhesins: nanomolar inhibitors of S. suis adhesins.

Four collections of Gal alpha1-4Gal derivatives were synthesised and evaluated as inhibitors of the PapG class II adhesin of uropathogenic Escherichia coli and of the P(N) and P(O) adhesins of Streptococcus suis strains. Galabiosides carrying aromatic structures at C1, methoxyphenyl O-galabiosides in particular, were identified as potent inhibitors of the PapG adhesin. Phenylurea derivatisation at C3' and methoxymethylation at O2' of galabiose provided inhibitors of the S. suis strains type P(N) adhesin with remarkably high affinities (30 and 50 nM, respectively). In addition, quantitative structure-activity relationship models for E. coli PapG adhesin and S. suis adhesin type P(O) were developed using multivariate data analysis. The inhibitory lead structures constitute an advancement towards high-affinity inhibitors as potential anti-adhesion therapeutic agents targeting bacterial infections.

Structural requirements for high-affinity heparin binding: alanine scanning analysis of charged residues in the C-terminal domain of human extracellular superoxide dismutase.

An essential property of human extracellular superoxide dismutase (hEC-SOD) is its affinity for heparin and heparan sulfate proteoglycans located on cell surfaces and in the connective tissue matrix. The C-terminal domain of hEC-SOD plays the major role in this interaction. This domain has an unusually high content of charged amino acids: six arginine, three lysine, and five glutamic acid residues. In this study, we used alanine scanning mutagenesis of charged amino acids in the C-terminal domain to elucidate the requirements for the heparin/heparan sulfate interaction. As a tool in this study, we used a fusion protein comprising the C-terminal domain of hEC-SOD fused to human carbonic anhydrase II (HCAII). The interaction studies were performed using the surface plasmon resonance technique and heparin-Sepharose chromatography. Replacement of the glutamic acid residues by alanine resulted, in all cases, in tighter binding. All alanine substitutions of basic amino acid residues, except one (R205A), reduced heparin affinity. The arginine and lysine residues in the cluster of basic amino acid residues (residues 210-215), the RK-cluster, are of critical importance for the binding to heparin, and arginine residues promote stronger interactions than lysine residues.

Capture and reconstitution of G protein-coupled receptors on a biosensor surface.

Surface plasmon resonance (SPR) biosensors offer a unique opportunity to study the binding activity of G protein-coupled receptors (GPCRs) in real time with minimal sample preparation. Using two chemokine receptors (CXCR4 and CCR5) as model systems, we captured the proteins from crude cell preparations onto the biosensor surface and reconstituted a lipid environment to maintain receptor activity. The conformational states of the receptors were probed using conformationally dependent antibodies, and by characterizing the binding properties of a native chemokine ligand (stromal cell-derived factor 1alpha). The results suggest that the detergent-solubilized receptors are active for ligand binding in the presence and absence of a reconstituted bilayer. There are three advantages to using this receptor-capturing approach: (1) there is no need to purify the receptor prior to immobilization on the biosensor surface, (2) the receptors are homogeneously immobilized through the capturing step, and (3) the receptors can be captured at high enough densities to allow the study of relatively low-molecular-mass ligands (2000-4000Da). We also demonstrated that the receptors are sensitive to the solubilizing conditions, which illustrates the potential for using SPR biosensors to rapidly screen solublization conditions for GPCRs.