Comparing Tyrosine Phosphorylation Changes after Erlotinib Treatment betweem Drug Sensitive and Drug Resistant Non-small Cell Lung Cancer Lines by Mass Spectrometry

Shih, Warren

15 February 2010

Non-Small-Cell-Lung Cancer (NSCLC) patients with mutations in EGFR have greater response rates and survival when treated with the tyrosine kinase inhibitor erlotinib. To elucidate how erlotinib inhibits EGFR, this study included: 1) inhibiting an EGFR mutant cell line to reveal EGFR regulated phosphotyrosine (pY) sites; 2) comparing erlotinib sensitive and insensitive cell lines to reveal functionally important pY sites; 3) revealing novel pY sites. Observations were collected using the LTQ-Orbitrap mass spectrometer. This study identified five new EGFR regulated pY sites and five pY sites that correlated with erlotinib sensitivity; the majority of them are related to cell-cell interactions. By comparing all observed pY sites to the Phosphosite and PhosphoELM database, our results included 67 unregistered sites. This study has identified novel biomarkers and potential therapeutic targets, many of which were associated with cell migration and adhesion function. Further functional validation is necessary.

EGFR

Non-Small Cell Lung Cancer

Erlotinib/Tarceva

Proteomics

Cell Signaling

0566

0992

0379

Global Quantitative Proteomic Profiling through 18O-labeling in Combination with MS/MS Spectra Analysis

White, Carl

30 December 2010

By integrating the simplicity of 18O-labeling and the low signal-to-noise of MS/MS spectra with supporting software and combining them with global shotgun protein identification, a robust quantitative pipeline has been created that avoids the disadvantages of other quantitative approaches. Test mixtures of labeled and unlabeled peptides were subjected to LC-MS/MS profiling experiments. Software programs were developed and applied to automatically determine protein ratios between two samples while applying a correction for incomplete labeling. The measurement of relative abundance at the product ion (MS/MS) level, instead of at the full scan (MS) level, is shown to provide excellent accuracy and sensitivity. Ratio distributions approached the expected means, allowing empirical derivation of confidence level cutoffs for determining statistically significant fold-changes in protein abundance. A set of stringent criteria for detecting spurious ratios based on consistency checking between unlabeled and labeled y-ion pairs was found to highlight putative false positive identifications.

proteomics

mass spectrometry

quantitative

stable isotope

profiling

protein

labeling

quantification

0307

Proteomic variations between a Mycoplasma gallisepticum vaccine strain and a virulent field isolate

Dennard, Rollin

11 August 2011

Mollicutes (mycoplasmas) are pathogenic in a wide range of mammals (including humans), reptiles, fish, arthropods, and plants. Of the medically important mollicutes, Mycoplasma gallisepticum is of particular relevance to avian agriculture and veterinary science, causing chronic respiratory disease in poultry and turkey. Using two-dimensional electrophoresis based quantitative expression proteomics, the current study investigated the molecular mechanisms behind the phenotypic variability between a M. gallisepticum vaccine strain (6/85) and a competitive, virulent field strain (K5234), two strains which were indistinguishable using commonly accepted genetic methods of identification. Twenty-nine proteins showed a significant variation in abundance (fold change > 1.5, p-value < 0.01). Among others, the levels of putative virulence determinants were increased in the virulent K5234, while the levels of several proteins involved with pyruvate metabolism were decreased. It is hoped that the data generated will further the understanding of M. gallisepticum virulence determinants and mechanisms of infection, and that this may contribute to the optimization of diagnostic methodologies and control strategies.

Mycoplasma gallisepticum

Mollicutes

Poultry vaccine

Expression proteomics

Two-dimensional electrophoresis

DIGE (Difference Gel Electrophoresis)

Biology, general

The Role Cranberry Proanthocyanidins Play in the Primary Attachment of Bacteria to Surfaces: Bacillus cereus Model

Jones, Anthony Robert

30 November 2008

The development of a proanthocyanidin (PAC) treatment, along with the understanding of its mechanism of action, would provide an alternative method of preventing attachment to and colonization of surfaces by microorganisms, as well as potentially disrupting preexisting biofilms. The purpose of this research is to examine the role a cranberry proanthocyanidin plays in the primary attachment of Bacillus cereus to an abiotic surface. This technology could be employed in food processing plants where a premium is placed on maintaining a sanitized work environment to prevent product contamination. A biofilm assay showed that a surface treated with proanthocyanidins actually promoted rather than prevented the attachment of Bacillus cereus. This was further made evident by the fact that the surface hydrophobicities of B. cereus cells grown in media supplemented with proanthocyanidins were greater than those grown in its absence. In addition, light microscopy analysis showed a greater degree of sporulation of B. cereus cells when grown on TSA plates supplemented with PACs. These results suggest that proanthocyanidins may be inducing endospore formation in Bacillus cereus leading to increased attachment and surface hydrophobicity values.

Mutagenesis

Proteomics

Bacillus cereus

Motility

Hydrophobicity

Biofilm

Attachment

Cranberry proanthocyanidins

Biology, general

Proteomic Analysis of the Response of Pseudomonas Aeruginosa PAO1 to the Cell to Cell Signaling Molecule Trans, Trans-farnesol of Candida Albicans

Jones-Dozier, Shelby L.

26 September 2008

Nosocomial infections associated with implanted medical- devices are on the rise due to a growing immunocompromised patient population. The organisms of interest in this study are Pseudomonas aeruginosa and Candida albicans. These organisms are opportunistic pathogens and are frequently implicated as the cause of infection and colonization of medical devices. P. aeruginosa is a motile gram-negative bacterium that is able to suppress the growth of C. albicans. Quourm sensing mimicry and biofilm formation on the hyphal surface of C. albicans by P. aeruginosa aids in suppression. C. albicans is a dimorphic fungus capable of quorum sensing with E,E-farnesol and is a central focus in this work. The goal of this project is to determine changes in protein expression when P. aeruginosa is exposed to E,E,-farnesol using 2D DIGE®. Changes in the cytosolic proteome of P. aeruginosa expose metabolic shifts that result in suppression of C. albicans. This work summarizes the effect of growth phase and concentration of E,E-farnesol on P. aeruginosa PAO1 and GSU3. Preliminary results reveal a general response of P. aeruginosa to C. albicans as changes in relevant metabolic nodes that affect pyocyanin production and the induction of virulence factors that lead to the killing of C. albicans. The overall goal of this study was to generate a profile of protein expression where a variety of conditions to further characterize the response could be easily assayed.

Candida albicans

proteomics

nosocomial infections

Pseudomonas aeruginosa

quorum sensing

attachment

medical devices

Biology, general

Characterizing soil organic nitrogen using advanced molecular analytical techniques

Gillespie, Adam Wattier

07 September 2010

Soil organic N (SON) comprises 90% of all N in surface soils, yet as much as half remains in forms which are chemically unknown or, at best, poorly understood. Analytical methods such has pyrolysis field-ionization mass spectrometry (Py-FIMS) and 15N cross polarization magic-angle spinning nuclear magnetic resonance (CPMAS-NMR) spectroscopy are widely used for the characterization of SON; however, these methods have limitations which contribute to the gaps in our understanding of SON chemistry. For example, Py-FIMS may produce heat-induced secondary compounds, and 15N-NMR may lack sensitivity and resolution for experiments at natural 15N abundance. X-ray absorption near edge structure (XANES) spectroscopy probes the bonding environment of individual elements. The application of this technique to complex environmental samples such as soil is still in its infancy, but early studies suggest that this technique may help resolve SON molecular structure. This dissertation sought to develop and apply synchrotron-based N and C K-edge XANES spectroscopy to the study of soil and soil extracts to determine the structures in which SON is bound. In these studies, Py-FIMS was coupled with XANES as a corroboratory technique.<p> Initial methodological development resulted in a calibration method whereby N2 gas generated in ammonium-containing salts was used to calibrate a soft X-ray beamline at the N K-edge. Although XANES can produce secondary compound artifacts, contrary to early assertions that it is a non-destructive technique, it was shown in a second study that beam-induced decomposition can be minimized by moving the beam to a fresh spot between scans.<p> Three applied studies exploring SON composition were conducted. These studies followed a spatial gradient ranging from the landscape scale, through a rhizosphere study, and ended with a study of glomalin-related soil protein (GRSP). Glomalin-related soil protein is a persistent soil glycoprotein of arbuscular mycorrhizal origin (AMF) implicated in aggregation and long-term C and N storage. Nitrogen and C K-edge XANES and Py-FIMS were used in all studies, and GRSP was further characterized using proteomics techniques.<p> Soil organic N composition was largely controlled by topographic position, and to a lesser degree, by cultivation. Divergent (i.e., water shedding) positions were enriched in carbohydrates and low molecular weight lignins, whereas convergent, depressional and level positions showed enrichment in lipid-type compounds. These differences were attributed to tillage-induced redistribution of soil, and water movement from upper to lower slope positions. Nitrogen XANES revealed a unique form of organic N, identified as N-bonded aromatics, particularly in the divergent positions.<p> Rhizosphere soil was enriched in higher molecular weight lipid-type materials and depleted in low molecular weight polar compounds. This was attributed to increased input of fresh plant material and higher microbial turnover in the rhizosphere. Nitrogen-bonded aromatics also were detected in the rhizosphere.<p> The GRSP extracts were characterized as mostly proteinaceous, but also contained many co-extracted, non-protein compounds. Despite being previously described as a glycoprotein, only weak carbohydrate signals were observed. Proteomics-based assessment of GRSP showed no homology to any proteins of AMF origin, instead showing homology with thioredoxin and with heat-stable soil proteins. This may be because protein databases do not yet contain glomalin-related sequences, or that glomalin is homologous to non-AMF soil proteins.<p> This dissertation demonstrated that N XANES is a sensitive and novel method for characterizing SON, and can be used complementarily with other analytical techniques such as Py-FIMS and proteomics. The continued development of XANES will provide a useful tool for SOM research into the future.

synchrotron

analytical chemistry

organic carbon

organic nitrogen

soil

pyrolysis

proteomics

glomalin

Adaptive responses of salmonella enterica serovar enteritidis ATCC 4931 biofilms to nutrient laminar flow and benzalkonium chloride treatment

Illathu, Anilkumar Mangalappalli

12 December 2007

<i>Salmonella enterica serovar Enteritidis</i> is an important biofilm-forming food-borne pathogen. This study examined the adaptive responses of <i>Salmonella serovar Enteritidis</i> biofilms to different environmental conditions such as flow velocity and benzalkonium chloride (BC) treatment. The influence of a 10-fold difference in nutrient laminar flow velocity on the dynamics of biofilm formation and protein expression profiles was compared. The mode of development and architecture of low-flow and high-flow biofilms were distinct. Exopolymer composition of the two biofilms was also different. However, no major shift in protein expression was seen between the biofilms, nor were there any stress response proteins involved. The biofilms altered their architecture in response to flow, presumably assuming a structure that minimized overall biofilm stress. An empirically-determined shear-inducing flow was applied on high-flow biofilms, fractionating the biofilms into shearable and non-shearable regions. Length:width indices of cells from the two biofilm regions, as well as planktonic cells from biofilm effluent and continuous culture were determined to be 3.2, 2.3, 2.2, and 1.7, respectively. Expression of proteins involved in cold-shock response, adaptation, and broad regulatory functions in the shearable region, and expression of protein involved in heat-shock response and chaperonin function in the non-shearable region indicated that the physiological status of cells in two biofilm regions was also distinct. The development of biofilm adaptive resistance to BC was then examined. Adapted biofilms survived a lethal BC challenge and re-grew, whereas unadapted biofilms did not. Proteins up-regulated following adaptation included those involved in energy metabolism, amino acid and protein biosynthesis, nutrient-transportation, adaptation, detoxification, and 1,2-propanediol degradation. A putative universal stress protein was also up-regulated. Cold-shock response, stress response, and detoxification are suggested to play roles in adaptive resistance to BC. Functional differences in adaptive response and survival of plankonic and biofilm cells adapted to BC were also studied. The proportion of BC-adapted biofilm cells that survived a lethal BC exposure and heat-shock was significantly higher than that of BC-adapted planktonic cells. Enhanced biofilm-specific up-regulation of various proteins, coupled with alterations in cell surface roughness and shift in fatty acid composition are proposed to function in the enhanced survival of BC-adapted biofilm cells, relative to BC-adapted planktonic cells.<p>It is concluded that biofilms adapt to the stress conditions by means of community, cellular, and sub-cellular level responses. These adaptive responses help the biofilms to enhance their ability for survival in the nature, especially those formed in critical environments such as healthcare facilities, the food industry, and households.

Benzalkonium chloride

Proteomics

Adaptive responses

Biofilms

Salmonella serovar Enteritidis

Microscopy

Nutrient laminar flow

Characterization of the White-rot Fungus, Phanerochaete carnosa, through Proteomic Methods and Compositional Analysis of Decayed Wood FibreCharacterization of the White-rot Fungus, Phanerochaete carnosa, through Proteomic Methods and Compositional Analysis of Decayed Wood Fibre

Mahajan, Sonam

10 January 2012

Biocatalysts are important tools for harnessing the potential of wood fibres since they can perform specific reactions with low environmental impact. Challenges to bioconversion technologies as applied to wood fibres include low accessibility of plant cell wall polymers and the heterogeneity of plant cell walls, which makes it difficult to predict conversion efficiencies. White-rot fungi are among the most efficient degraders of plant fibre (lignocellulose), capable of degrading cellulose, hemicellulose and lignin. Phanerochaete carnosa is a white-rot fungus that, in contrast to many white-rot fungi that have been studied to date, was isolated almost exclusively from fallen coniferous trees (softwood). While several studies describe the lignocellulolytic activity of the hardwood-degrading, model white-rot fungus Phanerochaete chrysosporium, the lignocellulolytic activity of P. carnosa has not been investigated. An underlying hypothesis of this thesis is that P. carnosa encodes enzymes that are particularly well suited for processing softwood fibre, which is an especially recalcitrant feedstock, though a major resource for Canada. Moreover, given the phylogenetic similarity of P. carnosa and P. chrysosporium, it is anticipated that the identification of pertinent enzymes for softwood degradation can be more easily conducted. In particular, this project describes the characterization of P. carnosa in terms of the growth conditions that support lignocellulolytic activity, the effect of enzymes secreted by P. carnosa on the chemistry of softwood feedstocks, and the characterization of the corresponding secretome using proteomic techniques. Through this study, cultivation methods for P. carnosa were established and biochemical assays for protein activity and quantification were developed. Analytical methods, including FTIR and ToF-SIMS were used to characterize wood samples at advancing stages of decay, and revealed preferential degradation of lignin in the early stages of growth on all softwoods analyzed. Finally, an in depth proteomic analysis of the proteins secreted by P. carnosa on spruce and cellulose established that similar sets of enzyme activities are elicited by P. carnosa grown on different lignocellulosic substrates, albeit to different expression levels.

softwood degradation, white-rot fungus

P. carnosa, proteomics, ToF-SIMS, FTIR

0542

Proteome-wide Analysis Of The Role Of Expression Of Bacilysin Operon On Idiophase Physiology Of B. Subtilis

Demir, Mustafa

01 January 2013

The members of the genus Bacillus produce a wide variety of secondary metabolites with antimetabolic and pharmacological activities. These metabolites are mostly small peptides and have unusual components and chemical bonds. These metabolites are synthesized nonribosomally by multifunctional enzyme complexes called peptide synthetases. One of those small peptides, bacilysin, is a dipeptide antibiotic composed of L-alanine and L-anticapsin which is produced and excreted by certain strains of Bacillus subtilis. Proteins that are responsible to synthesize bacilysin are encoded by bac operon. It has been shown that the biosynthesis of bacilysin is under the control of quorum sensing global regulatory pathway through the action of ComQ/ComX, PhrC (CSF), ComP/ComA in a Spo0K (Opp)-dependent manner. The objective of the study is to identify the functional roles of bacilysin biosynthesis in the regulatory cascade and idiophase cell physiology operating in B. subtilis by using gel-based and gel-free proteomics techniques. For this, we employed comparative proteome-wide analysis of the bacilysin producer B. subtilis PY79 and its bacilysin nonproducer derivative bacA::lacz::erm OGU1 strain which was recently constructed by our group. Identification via GeLC analysis of 76 differentially expressed proteins from total soluble proteome of wild-type PY79 and bacilysin minus OGU1 strain indicated the direct or indirect multiple effects of bacilysin on metabolic pathways, global regulatory systems and sporulation.

QR Bacteria 75-99.5

Characterization of the White-rot Fungus, Phanerochaete carnosa, through Proteomic Methods and Compositional Analysis of Decayed Wood FibreCharacterization of the White-rot Fungus, Phanerochaete carnosa, through Proteomic Methods and Compositional Analysis of Decayed Wood Fibre

Mahajan, Sonam

10 January 2012

Biocatalysts are important tools for harnessing the potential of wood fibres since they can perform specific reactions with low environmental impact. Challenges to bioconversion technologies as applied to wood fibres include low accessibility of plant cell wall polymers and the heterogeneity of plant cell walls, which makes it difficult to predict conversion efficiencies. White-rot fungi are among the most efficient degraders of plant fibre (lignocellulose), capable of degrading cellulose, hemicellulose and lignin. Phanerochaete carnosa is a white-rot fungus that, in contrast to many white-rot fungi that have been studied to date, was isolated almost exclusively from fallen coniferous trees (softwood). While several studies describe the lignocellulolytic activity of the hardwood-degrading, model white-rot fungus Phanerochaete chrysosporium, the lignocellulolytic activity of P. carnosa has not been investigated. An underlying hypothesis of this thesis is that P. carnosa encodes enzymes that are particularly well suited for processing softwood fibre, which is an especially recalcitrant feedstock, though a major resource for Canada. Moreover, given the phylogenetic similarity of P. carnosa and P. chrysosporium, it is anticipated that the identification of pertinent enzymes for softwood degradation can be more easily conducted. In particular, this project describes the characterization of P. carnosa in terms of the growth conditions that support lignocellulolytic activity, the effect of enzymes secreted by P. carnosa on the chemistry of softwood feedstocks, and the characterization of the corresponding secretome using proteomic techniques. Through this study, cultivation methods for P. carnosa were established and biochemical assays for protein activity and quantification were developed. Analytical methods, including FTIR and ToF-SIMS were used to characterize wood samples at advancing stages of decay, and revealed preferential degradation of lignin in the early stages of growth on all softwoods analyzed. Finally, an in depth proteomic analysis of the proteins secreted by P. carnosa on spruce and cellulose established that similar sets of enzyme activities are elicited by P. carnosa grown on different lignocellulosic substrates, albeit to different expression levels.

softwood degradation, white-rot fungus

P. carnosa, proteomics, ToF-SIMS, FTIR

0542