Positive and negative analyste ion yield in matrix-assisted laser desorption/ionizacion

Comunicaciones a congreso

A Bright, Slow Cryogenic Molecular Beam Source for Free Radicals

We demonstrate and characterize a cryogenic buffer gas-cooled molecular beam source capable of producing bright beams of free radicals and refractory species. Details of the beam properties (brightness, forward velocity distribution, transverse velocity spread, rotational and vibrational temperatures) are measured under varying conditions for the molecular species SrF. Under typical conditions we produce a beam of brightness 1.2 x 10^11 molecules/sr/pulse in the rovibrational ground state, with 140 m/s forward velocity and a rotational temperature of approximately 1 K. This source compares favorably to other methods for producing beams of free radicals and refractory species for many types of experiments. We provide details of construction that may be helpful for others attempting to use this method.Comment: 15 pages, 14 figure

The Buffer Gas Beam: An Intense, Cold, and Slow Source for Atoms and Molecules

Beams of atoms and molecules are stalwart tools for spectroscopy and studies of collisional processes. The supersonic expansion technique can create cold beams of many species of atoms and molecules. However, the resulting beam is typically moving at a speed of 300-600 m/s in the lab frame, and for a large class of species has insufficient flux (i.e. brightness) for important applications. In contrast, buffer gas beams can be a superior method in many cases, producing cold and relatively slow molecules in the lab frame with high brightness and great versatility. There are basic differences between supersonic and buffer gas cooled beams regarding particular technological advantages and constraints. At present, it is clear that not all of the possible variations on the buffer gas method have been studied. In this review, we will present a survey of the current state of the art in buffer gas beams, and explore some of the possible future directions that these new methods might take

High-Affinity Capture of Proteins by Diamond Nanoparticles for Mass Spectrometric Analysis

Carboxylated/oxidized diamond nanoparticles (nominal size 100 nm) exhibit exceptionally high affinity for proteins through both hydrophilic and hydrophobic forces. The affinity is so high that proteins in dilute solution can be easily captured by diamonds, simply separated by centrifugation, and directly analyzed by matrix-assisted laser desorption/ionization (MALDI) time-of-flight (TOF) mass spectrometry (MS). No preseparation of the adsorbed molecules from diamonds is required for the mass spectrometric analysis. Compared to conventional MALDI-TOF-MS, an enhancement in detection sensitivity by more than 2 orders of magnitude is achieved for dilute solution containing cytochrome c, myoglobin, and albumin because of preconcentration of the probed molecules. The lowest concentration detectable is 100 pM for a 1-mL solution. Aside from the enhanced sensitivity, the overall performance of this technique does not show any sign of deterioration for highly contaminated protein solutions, and furthermore, no significant peak broadening and band shift were observed in the mass spectra. The promise of this new method for clinical proteomics research is demonstrated with an application to human blood serum. Matrix-assisted laser desorption/ionization (MALDI) 1 time-offlight (TOF) mass spectrometry (MS) is a mainstream tool in current high-throughput mass analysis of biopolymers. 2 The MALDI technique, however, suffers from the shortcoming that it lacks sample specificity and its performance deteriorates markedly for samples containing multiple components and excessive amounts of salts or surfactants. 3 Surface-enhanced laser desorption/ ionization (SELDI) is one of the techniques 4-10 developed to circumvent these problems. In this method, 4 micrometer-sized (typically 80-300 µm in diameter) agarose beads made for affinity chromatography columns were used to capture proteins of interest in crude sample solutions. The microbeads were then recovered, washed, placed on the LDI probe tip, and analyzed with regular MALDI-TOF-MS. Unfortunately, direct analysis of the surfacebound proteins is often accompanied with undesired decrease in mass resolution as well as mass accuracy ascribed to the interference from the beads in ion formation and extraction. One solution to this problem is to directly immobilize proteins onto the surface of the LDI probe without use of the microbeads. 7 The approach again suffers from the shortcoming that the number of binding sites is quite limited, ∼1 × 10 13 molecules/cm 2 or ∼160 fmol/mm 2 for a single layer of proteins on the probe surface. The obstacle was later removed by immobilization of the proteins to high molecular weight dextrans precoated covalently on the LDI probe. 8 An approximate 500 times more sample could be loaded, although the dextran immobilization process is rather timeconsuming. We have previously shown 11 that diamond is an exceptional platform for protein adsorption and immobilization. The optical transparency, chemical inertness, and biological compatibility of the material endow diamond nanoparticles with novel and promising biotechnological applications. Preliminary tests with cytochrome c physisorbed to carboxylated/oxidized diamond particles of 5 and 100 nm in size indicate that the specially prepared diamond surfaces exhibit remarkably high affinity for proteins containing amino acid residues with basic side chains. This unique feature along with the fact that diamond is optically transparent up to the UV region motivated us to explore the possibility of using diamond nanoparticles for SELDI-TOF-MS. The advantage of using nanoparticles over microbeads is manyfold. First, nanoparticles have a much larger surface area-to-mass ratio, nearly 3 orders of magnitude higher than that of microbeads; second, the extent to which nanoparticles interfere with the laser desorption/ ionization process is diminished because of the smallness of the particles; third, nanoparticles can be embedded more firmly in the LDI matrix crystals than microbeads, thereby reducing material loss during sample preparation and analysis. There have been several applications of metallic, semiconducting as well as polymeric nanoparticles for mass spectrometric analysis of biopoly

Visualization of Spatiotemporal Energy Dynamics of Hippocampal Neurons by Mass Spectrometry during a Kainate-Induced Seizure

We report the use of matrix-assisted laser desorption/ionization (MALDI) imaging mass spectrometry combined with capillary electrophoresis (CE) mass spectrometry to visualize energy metabolism in the mouse hippocampus by imaging energy-related metabolites. We show the distribution patterns of ATP, ADP, and AMP in the hippocampus as well as changes in their amounts and distribution patterns in a murine model of limbic, kainate-induced seizure. As an acute response to kainate administration, we found massive and moderate reductions in ATP and ADP levels, respectively, but no significant changes in AMP levels—especially in cells of the CA3 layer. The results suggest the existence of CA3 neuron-selective energy metabolism at the anhydride bonds of ATP and ADP in the hippocampal neurons during seizure. In addition, metabolome analysis of energy synthesis pathways indicates accelerated glycolysis and possibly TCA cycle activity during seizure, presumably due to the depletion of ATP. Consistent with this result, the observed energy depletion significantly recovered up to 180 min after kainate administration. However, the recovery rate was remarkably low in part of the data-pixel population in the CA3 cell layer region, which likely reflects acute and CA3-selective neural death. Taken together, the present approach successfully revealed the spatiotemporal energy metabolism of the mouse hippocampus at a cellular resolution—both quantitatively and qualitatively. We aim to further elucidate various metabolic processes in the neural system

Accurate peak list extraction from proteomic mass spectra for identification and profiling studies

<p>Abstract</p> <p>Background</p> <p>Mass spectrometry is an essential technique in proteomics both to identify the proteins of a biological sample and to compare proteomic profiles of different samples. In both cases, the main phase of the data analysis is the procedure to extract the significant features from a mass spectrum. Its final output is the so-called peak list which contains the mass, the charge and the intensity of every detected biomolecule. The main steps of the peak list extraction procedure are usually preprocessing, peak detection, peak selection, charge determination and monoisotoping operation.</p> <p>Results</p> <p>This paper describes an original algorithm for peak list extraction from low and high resolution mass spectra. It has been developed principally to improve the precision of peak extraction in comparison to other reference algorithms. It contains many innovative features among which a sophisticated method for managing the overlapping isotopic distributions.</p> <p>Conclusions</p> <p>The performances of the basic version of the algorithm and of its optional functionalities have been evaluated in this paper on both SELDI-TOF, MALDI-TOF and ESI-FTICR ECD mass spectra. Executable files of MassSpec, a MATLAB implementation of the peak list extraction procedure for Windows and Linux systems, can be downloaded free of charge for nonprofit institutions from the following web site: <url>http://aimed11.unipv.it/MassSpec</url></p

Prediction of Extracellular Proteases of the Human Pathogen Helicobacter pylori Reveals Proteolytic Activity of the Hp1018/19 Protein HtrA

Exported proteases of Helicobacter pylori (H. pylori) are potentially involved in pathogen-associated disorders leading to gastric inflammation and neoplasia. By comprehensive sequence screening of the H. pylori proteome for predicted secreted proteases, we retrieved several candidate genes. We detected caseinolytic activities of several such proteases, which are released independently from the H. pylori type IV secretion system encoded by the cag pathogenicity island (cagPAI). Among these, we found the predicted serine protease HtrA (Hp1019), which was previously identified in the bacterial secretome of H. pylori. Importantly, we further found that the H. pylori genes hp1018 and hp1019 represent a single gene likely coding for an exported protein. Here, we directly verified proteolytic activity of HtrA in vitro and identified the HtrA protease in zymograms by mass spectrometry. Overexpressed and purified HtrA exhibited pronounced proteolytic activity, which is inactivated after mutation of Ser205 to alanine in the predicted active center of HtrA. These data demonstrate that H. pylori secretes HtrA as an active protease, which might represent a novel candidate target for therapeutic intervention strategies