Determination and control of low-level amino acid misincorporation in human thioredoxin protein produced in a recombinant Escherichia coli production system.

Escherichia coli is used extensively in the production of proteins within biotechnology for a number of therapeutic applications. Here, we discuss the production and overexpression of the potential biopharmaceutical human thioredoxin protein (rhTRX) within E. coli. Overexpression of foreign molecules within the cell can put an enormous amount of stress on the translation machinery. This can lead to a misfiring in the construction of a protein resulting in populations differing slightly in amino acid composition. Whilst this may still result in a population of active molecules being expressed, it does present significant problems with molecules that are destined for clinical applications. Amino acid misincorporation of this subset could potentially result in antibodies being raised to these unnatural proteins. Cross-reaction with a patient's endogenous thioredoxin could then lead to an autoimmune phenomena and serious health implications. Generally, the issue of misincorporation appears not to be a routine regulatory concern (see ICH Q6B guidelines). Therefore, amino acid misincorporation may not have been detected, much less explored in the clinic as the occurrence or absence of these random errors is not routinely reported. Using current technologies based on proteomics, the ability to find misincorporation critically depends upon the criteria for matching theoretical and experimental mass spectrometry data. Additionally, isolation and extraction of these mistranslated proteins from the production process is both difficult and expensive. Therefore, it is advantageous to find routes for removing their production during the upstream phase. In this study, we show how modern proteomic technology can be used to identify and quantify amino acid misincorporation. Using these techniques we have shown how manipulation of gene sequence and scoping of fermentation media composition can lead to the reduction and elimination of these misincorporations in rhTRX.

Peptide nucleic acid probes with charged photocleavable mass markers: Towards PNA-based MALDI-TOF MS genetic analysis.

Halogen-labelled peptide organic acid (HPOA) monomers have been synthesised and incorporated into sequence-specific peptide nucleic acid (PNA) probes. Three different types of probe have been prepared; the unmodified PNA probe, the PNA probe with a mass marker, and the PNA probe with photocleavable mass marker. All three types of probe have been used in model studies to develop a mass spectrometry-based hybridisation assay for detection of point mutations in DNA.

On-line capillary column immobilised metal affinity chromatography/electrospray ionisation mass spectrometry for the selective analysis of histidine-containing peptides.

Capillary column immobilised metal affinity chromatography (IMAC) has been combined on-line with electrospray ionisation/quadrupole time-of-flight mass spectrometry for the fractionation of histidine-containing peptides. IMAC beads (Poros 20MC, 20 microm) containing imidodiacetate chelating groups on a cross-linked poly(styrene-divinylbenzene) support were packed into a fused silica column (250 microm i.d.), which was interfaced to the electrospray ion source of the spectrometer. A Cu(II) activated column was used to isolate histidine-containing peptides from tryptic and other peptide mixtures with an average breakthrough of 9.1%, to reduce the complexity of the mass spectral analysis. The analysis cycle time was reduced to less than 15 min, at an optimum flow rate of 7.5 microL/min, without sacrificing peptide selectivity. Direct coupling of capillary IMAC with MS allows on-line separation, using MS compatible loading and elution buffers, and detection in a high-throughput fashion when compared to off-line strategies.

Analysis of tryptic peptides using desorption electrospray ionisation combined with ion mobility spectrometry/mass spectrometry.

A novel method is reported for rapid protein identification by the analysis of tryptic peptides using desorption electrospray ionisation (DESI) coupled with hyphenated ion mobility spectrometry and quadrupole time-of-flight mass spectrometry (IMS/Q-ToF-MS). Confident protein identification is demonstrated for the analysis of tryptically digested bovine serum albumin (BSA), with no sample pre-treatment or clean-up. Electrophoretic ion mobility separation of ions generated by DESI allowed examination of charge-state and mobility distributions for tryptic peptide mixtures. Selective interrogation of singly charged ions allowed isobaric peptide responses to be distinguished, along with a reduction in spectral noise. The mobility-selected singly charged peptide responses were presented as a pseudo-peptide mass fingerprint (p-PMF) for protein database searching. Comparative data are shown for electrospray ionisation (ESI) of the BSA digest, without sample clean-up, from which confident protein identification could not be made. Implications for the robustness of the DESI method, together with potential insights into mechanisms for DESI of proteolytic digests, are discussed.

An estrogen-platinum terpyridine conjugate: DNA and protein binding and cellular delivery.

A platinum metal complex in which terpyridine joins estradiol (via an ethynyl link) to a platinum with a labile ligand (chloride) has been designed, synthesised and its X-ray crystal structure determined. The aim of this work was to link a targeting motif (in this case estrogen) to a metal-based biomolecule recognition unit (the platinum moiety). The target molecule: 17alpha-[4'-ethynyl-2,2':6',2'-terpyridine]-17beta-estradiol platinum(II) chloride (PtEEtpy) has been shown to bind to both human and bovine serum albumin (SA) and to DNA. FTICR mass spectrometry shows that the bimolecular units are in each case linked through coordination to the platinum with displacement of the chloride ligand. Circular dichroism indicates that a termolecular entity involving PtEEtpy, SA and DNA is formed. A range of electrospray mass spectrometry experiments showed that the PtEEtpy complex breaks and forms coordination bonds relatively easily. A whole cell estrogen receptor assay in an estrogen receptor positive cell (MCF-7) confirms binding of both EEtpy and PtEEtpy to the estrogen receptor in cells. The work demonstrates the concept of linking a targeting moiety (in this case estrogen) to a DNA binding agent.

Capillary liquid chromatography/atmospheric-pressure matrix-assisted laser desorption/ionisation ion trap mass spectrometry: a comparison with liquid chromatography/matrix-assisted laser desorption/ionisation time-of-flight and liquid chromatography/electrospray ionisation quadrupole time-of-flight for the identification of tryptic peptides.

The atmospheric-pressure matrix-assisted laser desorption/ionisation quadrupole ion trap (AP-MALDI-QIT) analysis of tryptic peptides is reported following capillary liquid chromatographic (LC) separation and direct analysis of a protein digest. Peptide fragments were identified by peptide mass fingerprinting from mass spectrometric data and sequence analysis obtained by tandem mass spectrometry of the principal mass spectral peaks using a data-dependent scanning protocol. These data were compared with those from mass spectrometric analysis using capillary LC/MALDI-time-of-flight (TOF) and capillary LC/electrospray ionisation (ESI)-quadrupole TOF. For all three configurations the resulting data were searched against the MSDB database, using MASCOT and the sequence coverage compared for each technique. Complementary data were obtained using the three techniques.