Comparison of Label and Label-free Quantitative Liquid Chromatography Tandem Mass Spectrometry for Protein Biomarker Discovery

Zhao, Bei

02 November 2010

No description available.

Chemistry

mass spectrometry

label-free

tandem mass tag

Approaches to high throughput physical organic chemistry

Portal, Christophe

January 2008

Over the past ten years, the development of High Throughput (HT) synthetic chemistry techniques has allowed the rapid preparation of libraries of hundreds to thousands of compounds. These tools are now extensively used for drug and material discovery programmes. The subsequent development of analytical capabilities to carry out qualitative and quantitative assessment of the compounds generated by HT synthesis as well as their HT screening has led to a dramatic broadening of the scope of HT techniques, ranging from image based analysis techniques to mass spectrometry (MS). Based on the latter, a range of solid phase and solution phase analytical constructs was developed to enable the qualitative and quantitative assessment of mixtures of small compounds, using positive electrospray MS as the sole analytical tool. A version of the construct allowed HT reactivity profiling to be carried out on a range of ten carboxylic acids, ten aldehydes and ten isonitriles in the Ugi 4-component condensation reaction. The effect of various parameters such as the concentration of the monomers on the reactivity was investigated. The elaboration of a HT Hammett parameter assessment method was made possible by the development of an electrophilic version of the construct. The value of the Hammett value was afforded by means of combinatorial Hammett plots and values were successfully evaluated in a HT mode for around thirty anilines with substituents in the meta and para position of the aromatic ring. Finally, analytical constructs were used in an attempt to evaluate enzyme reaction kinetics via the labelling of peptides and small drug fragment with coded constructs, to afford affinity determinations between the enzyme (protease) and peptidic or fragment based substrates.

547.13

Glycopeptide Enrichment Workflows for Downstream Mass Spectrometric Analysis

Bodnar, Edward

01 November 2013

Mass spectrometry (MS) is a power analytical tool which is capable of analyzing biomolecules in great detail, both structurally and quantitatively. With regards to glycans, special considerations regarding sample preparation are necessary in order to achieve reproducible identification and relative quantification of these analytes. A workflow for isolation at the glycopeptide level and subsequent detection at the glycan level with phenylhydrazine, demonstrated that monoclonal antibodies (mAbs) containing a specific amino acid mutation were able to express approximately an additional 50% of the α2,6 disialylated glycan compared to their non-mutant analogues. In a second experiment using mAbs, an azide modified glycan (Ac4ManAz) was introduced both metabolically and enzymatically during mAb production. This glycan is a precursor in the sialic acid pathway and the azide moiety allows for specific chemistry post-production including the potential for highly specific enrichment. The results of this workflow demonstrated that [100 μM] of Ac4ManAz precursor added to the cell media was necessary for metabolic expression. More complex samples however, may contain multiple sites of glycosylation. To conserve the site of attachment, these molecules are often studied at the glycopeptide level, and require enrichment of glycopeptides to improve the lower signal intensity observed in the presence of co-eluting peptides. Carboxymethyl chitosan (CMCH) as well as amine-functionalized magnetic-nanoparticles (MNP) were developed as novel materials for this purpose. CMCH is naturally occurring, and therefore is cost-effective and readily available. In a 12 protein mixture CMCH demonstrated the bulk enrichment of glycopeptides yielding an approximately 20% higher enrichment of sialylated species as compared to a commercially available glycopeptide kit through the use of tandem mass tags for relative quantification. In the same approach, amine functionalized MNP were produced and used to enrich glycopeptides from tryptic digests. This approach was fast (about 10 mins) and quantitatively demonstrated improved retention for sialylated species. Examples of these techniques and their applications are reported in this work. / October 2015

Mass Spectrometry

Glycan

Tandem Mass Tag

Workflow

Enrichment

Sugar

Chemistry

Monoclonal Antibody

Immunoglobulin

Sialylation

Pharmaceutical

Herceptin

Trastuzamab

Solid Phase Extraction

Click chemistry

Azido sugar

iTRAQ

MALDI

Développement de nouvelles réactions de click in situ appliquées à la synthése d'inhibiteurs de la β-sécrétase. / Synthesis of bio-organic tools for the development of new in situ click reaction applied to the synthesis of β-secretase inhibitors

Lizzul-Jurse, Antoine

13 January 2017

La synthèse contrôlée par la cible sous contrôle cinétique (Kinetic Target-Guided Synthesis, KTGS) est une approche relativement peu explorée, alternative à la chimie combinatoire traditionnelle,dans laquelle la protéine cible participe à la synthèse du ou de ses propres ligands. Ainsi, les travaux présentés dans la première partie de cette thèse ont pour principal objectif d'élargir l'éventail des réactions actuellement disponibles en KTGS grâce à la réaction d'aldolisation voire d'amidation, et ce en utilisant la β-sécrétase (BACE-1) comme cible biologique, qui est une enzyme étroitement impliquée dans la maladie d'Alzheimer. La seconde partie de cette thèse a été consacrée à la synthèse de marqueurs de masse fluorescents bioconjugables basés sur l'association d'un noyau coumarinique et d'une fonction phosphonium. Les deux générations présentées dans ce manuscrit ont entre autre permis de synthétiser une sonde FRET permettant de détecter l'activité enzymatique de la BACE-1, qui pourrait par ailleurs être un outil intéressant pour l'analyse des bruts réactionnels des réactions de click in situ,et diminuer les quantités d'enzyme engagées dans ces expériences. Enfin dans la dernière partie de cette thèse nous décrivons la mise au point de nouvelles réactions de conjugaison bio-orthogonale pour le marquage de molécules comportant une fonction aldéhyde. Nous avons ainsi développé d'une part une réaction trois composants via une séquence de condensation/Mannich/lactamisation et d'autre part une réaction d'oléfination de Wittig. / The kinetic target-guided synthesis (KTGS), is an underexplored alternative approach to combinatorial chemistry, in which the biological target is able to assemble its own inhibitors from a pool of fragments. Thus, the first part of this thesis aimed at extending the scope of the reactions available for the KTGS, by investigating the aldolisation and amidation reaction, using the β-secretase (BACE-1) as biological target, which is an enzyme narrowly involved in the Alzheimer's disease. The second part of this thesis was dedicated to the synthesis of bioconjagatable fluorophores containing a phosphonium group as mass tag associated to a coumarin core. Both generations presented in this manuscript allowed us, among other things, to synthesize a FRET probe that proved suitable for the determination of BACE-1 enzymatic activity. The utility of such a fluorogenic tool could be leveraged to facilitate the analysis of crude mixtures obtained during KTGS experiments, and lessen the amount of enzyme required in these experiments. Finally, in the last part of this thesis, we describe the development of two new bioorthogonal reactions allowing the selective labeling of molecules containing an aldehyde moiety : 1) a three component reaction involving a condensation/Mannich/lactamisation procedure, between an amine, an aldehyde and an enol partner; 2) a Wittig ligation between an aldehyde and a phosphonium bearing an active methylene.

Dir. chimie

BACE-1

Marqueur de masse

Coumarine

Phosphonium

Conjugaison bio-orthogonale

Kinetic target-guided synthesis

BACE-1

Mass tag

Coumarin

Phosphonium

Bioorthogonal conjugation

541.39