Haemagglutinin quantification and identification of influenza A&B strains propagated in PER.C6 cells: a novel RP-HPLC method.

The major antigenic determinant of influenza A and B virus is haemagglutinin (HA). The HA content is an important specification of influenza vaccines. HA in vaccines has typically been quantified by single-radial-immunodiffusion (SRID). However, SRID is a laborious and low throughput assay. Moreover, sensitivity, accuracy, and precision, especially for non-purified (in-process) influenza virus is relatively low. We present a novel method for quantification of HA in influenza viral cultures as well as for the identification of HA from individual influenza strains in trivalent vaccines. The method is based on the separation of HA(1), the hydrophilic subunit of HA, from the more hydrophobic viral and matrix components by reversed-phase high performance liquid chromatography (RP-HPLC). The HA(1) peak area is demonstrated to be proportional to the level of HA in non-purified, semi-purified and purified vaccine products of various epidemic and pandemic influenza A and B strains propagated in PER.C6((R)) cell cultures. The RP-HPLC assay selectivity allows for the simultaneous identification and quantification of HA(1) from influenza A and B strains in the yearly revised trivalent vaccines for epidemic outbreaks.

Combined in-gel tryptic digestion and CNBr cleavage for the generation of peptide maps of an integral membrane protein with MALDI-TOF mass spectrometry.

A limitation of the in-gel approaches for the generation of peptides of membrane proteins is the size and hydrophobicity of the fragments generated. For membrane proteins like the lactose transporter (LacS) of Streptococcus thermophilus, tryptic digestion or CNBr cleavage yields several hydrophobic fragments larger than 3.5 kDa. As a result, the sequence coverage of the membrane domain is low when the in-gel tryptic-digested or CNBr-cleaved fragments are analyzed by matrix-assisted laser desorption/ionization-time-of-flight (MALDI-TOF) mass spectrometry (MS). The combination of tryptic digestion and subsequent CNBr cleavage on the same gel pieces containing LacS approximately doubled the coverage of the hydrophobic membrane domain compared to the individual cleavage methods, while the coverage of the soluble domain remained complete. The fragments formed are predominantly below m/z 2500, which allows accurate mass measurement.

Improved in-gel approaches to generate peptide maps of integral membrane proteins with matrix-assisted laser desorption/ionization time-of-flight mass spectrometry.

This paper reports studies of in-gel digestion procedures to generate MALDI-MS peptide maps of integral membrane proteins. The methods were developed for the membrane domain of the mannitol permease of E. coli. In-gel digestion of this domain with trypsin, followed by extraction of the peptides from the gel, yields only 44% sequence coverage. Since lysines and arginines are seldomly found in the membrane-spanning regions, complete tryptic cleavage will generate large hydrophobic fragments, many of which are poorly soluble and most likely contribute to the low sequence coverage. Addition of the detergent octyl-beta-glucopyranoside (OBG), at 0.1% concentration, to the extraction solvent increases the total number of peptides detected to at least 85% of the total protein sequence. OBG facilitates the recovery of hydrophobic peptides when they are SpeedVac dried during the extraction procedure. Many of the newly recovered peptides are partial cleavage products. This seems to be advantageous since it generates hydrophobic fragments with a hydrophilic solubilizing part. In-gel CNBr cleavage resulted in 5-10-fold more intense spectra, 83% sequence coverage, fully cleaved fragments and no effect of OBG. In contrast to tryptic cleavage sites, the CNBr cleavage sites are found in transmembrane segments; cleavage at these sites generates smaller hydrophobic fragments, which are more soluble and do not need OBG. With the results of both cleavages, a complete sequence coverage of the membrane domain of the mannitol permease of E. coli is obtained without the necessity of using HPLC separation. The protocols were applied to two other integral membrane proteins, which confirmed the general applicability of CNBr cleavage and the observed effects of OBG in peptide recovery after tryptic digestion.

Purification, crystallization and preliminary X-ray diffraction of Cys103Ala acyl coenzyme A: isopenicillin N acyltransferase from Penicillium chrysogenum.

Penicillins and cephalosporins are an efficacious group of antibiotics produced by fungi such as Penicillium chrysogenum and Acremonium chrysogenum. The last step in their biosynthesis is catalyzed by acyl coenzyme A:isopenicillin N transferase (AT). This enzyme is produced as a single-chain proenzyme, which is activated by autocatalytic cleavage of the Gly102-Cys103 peptide bond, resulting in a heterodimeric protein with subunits of 11 and 29 kDa. The Cys103Ala mutant of the proenzyme, which does not undergo this cleavage, was purified and crystallized. Diffraction-quality crystals of the mutant and an L-SeMet-substituted mutant were obtained by vapour diffusion against solutions containing (NH(4))(2)SO(4), NaCl and HEPES-NaOH pH 7.5. The crystals belong to the monoclinic space group C2, with unit-cell parameters a = 231.36, b = 68.27, c = 151.31 A and beta = 129.56 degrees. They diffract to 2.8 A resolution with X-rays from a rotating-anode generator.

Mapping of the dimer interface of the Escherichia coli mannitol permease by cysteine cross-linking.

A cysteine cross-linking approach was used to identify residues at the dimer interface of the Escherichia coli mannitol permease. This transport protein comprises two cytoplasmic domains and one membrane-embedded C domain per monomer, of which the latter provides the dimer contacts. A series of single-cysteine His-tagged C domains present in the native membrane were subjected to Cu(II)-(1,10-phenanthroline)(3)-catalyzed disulfide formation or cysteine cross-linking with dimaleimides of different length. The engineered cysteines were at the borders of the predicted membrane-spanning alpha-helices. Two residues were found to be located in close proximity of each other and capable of forming a disulfide, while four other locations formed cross-links with the longer dimaleimides. Solubilization of the membranes did only influence the cross-linking behavior at one position (Cys(73)). Mannitol binding only effected the cross-linking of a cysteine at the border of the third transmembrane helix (Cys(134)), indicating that substrate binding does not lead to large rearrangements in the helix packing or to dissociation of the dimer. Upon mannitol binding, the Cys(134) becomes more exposed but the residue is no longer capable of forming a stable disulfide in the dimeric IIC domain. In combination with the recently obtained projection structure of the IIC domain in two-dimensional crystals, a first proposal is made for alpha-helix packing in the mannitol permease.