Mehmet Atakay

Comparison of two methods for purification of enterocin B, a bacteriocin produced by Enterococcus faecium W3.

This study aimed to compare two different approaches for the purification of enterocin B from Enterococcus faecium strain W3 based on the observation that the bacteriocin was found both in cell associated form and in culture supernatant. The first approach employed ammonium sulfate precipitation, cation-exchange chromatography, and sequential reverse-phase high-performance liquid chromatography. The latter approach exploited a pH-mediated cell adsorption–desorption method to extract cell-bound bacteriocin, and one run of reverse-phase chromatography. The first method resulted in purification of enterocin B with a recovery of 4% of the initial bacteriocin activity found in culture supernatant. MALDI-TOF MS analysis and de novo peptide sequencing of the purified bacteriocin confirmed that the active peptide was enterocin B. The second method achieved the purification of enterocin B with a higher recovery (16%) and enabled us to achieve pure bacteriocin within a shorter period of time by avoiding time consuming purification protocols. The purity and identity of the active peptide were confirmed again by matrix-assisted laser desorption/ionization time-of flight (MALDI-TOF) mass spectrometry (MS) analysis. Although both approaches were satisfactory to obtain a sufficient amount of enterocin B for use in MS and amino acid sequence analysis, the latter was proved to be applicable in large-scale and rapid purification of enterocin B.

A Trypsin Immobilized Sol-Gel for Protein Indentification in MALDI-MS Applications

The proteolytic enzyme trypsin was chemically immobilized to an amine-functionalized sol-gel using adipoyl chloride under nonaqueous conditions and a nitrogen atmosphere. In the synthesis of the sol-gel, tetraethyl orthosilicate (TEOS), and 3-(2-aminoethylamino) propyldimethoxymethylsilane (AEAPMS) (50:50, v/v) were used, which provided convenient physical and chemical conditions to maintain catalytic activity of immobilized trypsin molecules for the digestion of proteins in proteomics applications. Bovine serum albumin was used as a model protein to perform enzymatic digestion using the trypsin immobilized sol-gel. The resulting peptides were analyzed by matrix-assisted laser desorption/ionization-mass spectrometry to evaluate the digestion performance and specificity of the sol-gel material. The trypsin immobilized sol-gel showed superior enzymatic activity in protein digestion and it was determined that the sol-gel material could be repeatedly used at least 25 times without significant activity loss in long-term use. Additionally, autocatalysis was prevented by immobilization of trypsin. The peptide digest having the highest purity was obtained for protein identification studies.

Specific enrichment and direct detection of phosphopeptides on insoluble transition metal oxide particles in matrix-assisted laser desorption/ionization mass spectrometry applications.

Several transition metal oxides, such as iron (III), nickel (II) and zirconium (IV) oxides, were examined in detail for the specific enrichment and the purification of phosphopeptides from a digested peptide mixture solution. Phosphopeptide enrichment was performed on the metal oxide particles using a peptide mixture obtained by tryptic digestion of β-casein. The mixture of protein digests containing bovine serum albumin (BSA):β-casein digests (100: 1 mole ratio) was also used for the phosphopeptide enrichment. Furthermore, non-fat milk digest was examined as a complex biological sample. In each phosphopeptide enrichment process, phosphopeptides were specifically enriched and separated from the non-phosphopeptides. The phosphopeptides were adsorbed onto the metal oxide surface at acidic pH values between 1.0 and 2.0 and, for desorption of phosphopeptides from metal oxide particles, pH values were examined and optimized in the enrichment studies. The analysis of phosphopeptides were carried out by matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) using 2,5-dihydroxybenzoic acid matrix containing 1.0% phosphoric acid to obtain intense protonated signals and to overcome degradation of the phosphopeptides by phosphate group loss in mass spectrometric conditions. Moreover, it was demonstrated that the direct detection of phosphopeptides from the surface of the metal oxide particles was possible using MALDI-MS by mixing the phosphopeptide–adsorbed metal oxide particles with MALDI matrix solution in slurry form before the analysis. Thus, the effects of interferences arising from chemical species used in the desorption process was successfully eliminated for the fast and sensitive detection of phosphopeptides in MALDI-MS applications.

Synthesis and characterization of amphiphilic triblock copolymers including β-alanine/α-methyl-β-alanine and ethylene glycol by “click” chemistry

Terminally azide poly-β-alanine (PBA-Az) was directly obtained by hydrogen transfer polymerization of acrylamide in the presence of sodium azide as an initiator. However, terminally azide poly(α-methyl β-alanine) (PmBA-Az) was synthesized by the reaction between terminally bromo poly(α-methyl β-alanine) and sodium azide. Dipropargyllated polyethylene glycol (PEG-di-Pr) was synthesized by using the reaction of PEGs with different molecular weights and propargyl bromide. Synthesis of poly(β-alanine-b-ethylene glycol-b-β-alanine) and poly(α-methyl β-alanine-b-ethylene glycol-b-α-methyl β-alanine) amphiphilic ABA triblock copolymers was achieved via “click” chemistry of PBA-Az or PmBA-Az and PEG-di-Pr with different molecular weight. “Click” reaction parameters such as concentration and time were assessed. Macromonomers and the amphiphilic triblock copolymers were characterized by using 1H-NMR, FT-IR, MALDI-MS, TGA, and elemental analysis techniques. The multi-instruments studies of the obtained amphiphilic triblock copolymers reveal that the copolymers easily formed as a result of “click” chemistry.

Use of Sulfonates as Desorption Agents for Phosphopeptide Elution from an Anion-exchange Material

ABSTRACT In general, phosphopeptides are specifically adsorbed to the surface of the material at the initial step of phosphopeptide enrichment methods. Thus, nonphosphopeptides can be removed from the media by following the appropriate washing steps. After sufficient washing, the phosphopeptides are eluted from the surface of the material completely for further analysis. Performing the elution of phosphopeptides fully in the enrichment step is very important in terms of determining the whole phosphoproteome profile of a sample by subsequent mass spectrometric analysis. Materials containing anion exchanger groups such as amines on the surface can be used as a selective stationary phase in phosphopeptide enrichment methods. Positively charged groups on the surface of this type of material interact with the phosphate groups of phosphopeptides through electrostatic interactions. Such interactions can be basically manipulated by changing the pH of the medium or replacing the salts present in the solution. Phosphopeptides attached to the surface of anion-exchange materials may be displaced with the addition of highly acidic compounds such as sulfonates to the enrichment medium. Here, we used various sulfonates as desorption agents for the elution of retained phosphopeptides from the surface of an anion-exchange material. We found that differences in the chemical structures and properties of the sulfonates remarkably affected phosphopeptide retrieval from the anion-exchange material.