Browsing by Subject "proteins"
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Item Development of a MALDI-Ion Mobility-Surface-Induced Dissociation-Time-of-flight-mass spectrometer for the analysis of peptides and proteins(Texas A&M University, 2004-09-30) Stone, Earle GregoryPeptide sequencing by surface-induced dissociation (SID) on a MALDI-Ion Mobility-orthogonal-TOF mass spectrometer is demonstrated. The early version of the instrument used for proof-of-concept experiments achieves a mobility resolution of approximately 20 and TOF mass resolution better than 200. Peptide sequences of four peptides from a tryptic digest of cytochrome c (ca. 1 pmol deposited) were obtained. The advantage of IM-SID-o-TOFMS is that a single experiment can be used to simultaneously measure the molecular weights of the tryptic peptide fragments (peptide mass mapping) and partial sequence analysis, (real time tandem mass spectrometry.) Optimization of the MALDI-IM-SID-o-TOF mass spectrometer for peptide sequencing is discussed. SID spectra obtained by using stainless steel, Au grids, and fluorinated self-assembled monolayers (F-SAM) on Au are compared. Optimum collision energies differ for the various surfaces. The fragmentation patterns observed for a series of peptides and protein digests using the Nd:YAG laser (355 nm) for MALDI ion formation and an FSAM surface for ion activation is compared to the fragmentation patterns observed for CID and photodissociation. The fragmentation patterns observed in all cases are strikingly similar. Photodissociation produced a greater abundance of ions resulting from side-chain cleavages. As a general rule optimized SID spectra contain fewer immonium ions than either photodissociation or CID. Evaluation of an instrument incorporating a new hybrid drift cell is discussed. Spectra for a digest of hemoglobin is compared to that acquired with an ABI 4700 TOF-TOF. The performance of the instrument is also evaluated using a micro-crystal Nd:YAG laser (355 nm) for MALDI operated at 400 Hz. Experiments were performed to determine the sensitivity and overall performance of the instrument. The reproducibility of the MS/MS spectra for gramicidin S is shown to be 94% run-to-run. The best mobility resolution obtained for a neat deposition of the dye Crystal Violet was 60 t/?t. Sensitivity was tested with the peptide fibrinopeptide A (m/z 1537, AA sequence ADSGEGDFLAEGGGVR). Data acquired for sixty seconds with approximately sixty femtomoles deposited. Abundant [M+H]+ ions where observed as well as [M+H]+-NH3 ions. The S/N for this short run was insufficient to identify any SID fragmentsItem Fluorescent Labeling Reagents Optimized for Capillary Electrophoretic Separations(2012-02-14) Estrada, Roy Tonacao, IIIFluorescent labeling can improve the detection sensitivity in capillary electrophoretic (CE) separations down to attomolar concentrations. However, most fluorescent labels are not compatible with CE because their fluorescence properties and charge states are pH-dependent, they are often hydrophobic and they have a tendency to significantly change the properties of the analytes after labeling. A group of fluorescent labeling reagents have been prepared whose fluorophores have properties that are optimized for CE separations. These fluorophores have fluorescence properties and charge states that are independent of pH in the 2 < pH < 11 range. Their excitation maxima are also compatible with the 488 nm line of the Argon ion laser. A mono-cationic acridine-based fluorescent label was prepared and was found to not shift the pI of a labeled model protein in capillary isoelectric focusing separation (cIEF). Lower loading, due to increased sensitivity, led to better resolution of closely spaced isoform peaks having a pI = 0.05. A tri-anionic pyrene-based fluorescent labeling reagent was also synthesized and was used in the sodium dodecyl sulfate capillary gel electrophoresis (SDS-CGE) separation of proteins. The fluorophore led to an LOQ in the nM range, and did not alter the migration behavior of proteins in the sieving matrix. A third fluorescent labeling reagent was developed as a solid phase reagent (SPR) where the fluorophore was immobilized on a solid surface through a cleavable anchor. The fluorophore is di-anionic and is based on pyrene. The SPR was designed to allow the simultaneous capture and labeling of an analyte and the efficient release of the label-analyte conjugate under mild acidic conditions. The use of the SPR allowed the labeling of a diamine whose concentration was in the low nanomolar range. The SPR opens up the possibility for mono-labeling and proportional multiple labeling of proteins.