Synthesis and in vitro applications of fluorescent imaging agents

Brunet, Aurelie Claude Laure

January 2014

Fluorescent imaging technologies that offer new ways to visualise and quantify fluorescently labelled molecules are increasing, necessitating the development of fluorescent molecules that can efficiently and specifically label targets in vitro and in vivo. The first aim of this thesis was the study of human neutrophil elastase. Human neutrophil elastase is an important enzyme in the regulation of inflammation but if over expressed can become part of the cause of inflammation itself. To elucidate this dual function and have a greater understanding of this enzyme, an imaging probe for neutrophil elastase was designed. Firstly, the syntheses of fluorescently labelled three branched dendron core structures were optimised, and studied in neutrophils. The selected core structure was functionalised with an elastase specific peptide sequence and fluorescently labelled. The probe was specifically cleaved by neutrophil elastase in an enzymatic assay and in the presence of activated neutrophils (Chapter 1). Fluorescein and rhodamine are dyes that are readily available, are affordable and have convenient wavelengths for microscopy and flow cytometry. Carboxyfluorescein diacetate N-succinimidyl ester (CFDA-SE) is a commonly used fluorescein derivative, widely used in cell proliferation assay. It is mainly used as a mixture of isomers and its synthesis is not reported. Herein a short and simple synthesis of the two individual isomers of carboxyfluorescein diacetate N-succinimidyl ester as well as the equivalent rhodamine variation (carboxytetraethylrhodamine N-succinimidyl ester) is reported (Chapter 2). The labelling properties of these probes were studied in proliferation assays on mouse and human T lymphocytes. Finally, the nuclear penetration of the dendron structure combined with nuclear localisation sequences (NLS) was investigated. Attachment of nuclear localisation sequences to the probe in the presence of fluorescein demonstrated successful entry into the nucleus in human alveolar adenocarcinoma cell line (A549) (Chapter 3).

572

Synthesis and Characterization of Potential Drug Delivery Systems using Nonionic Surfactant “Niosome”

Leekumjorn, Sukit

24 March 2004

Niosomes are synthetic microscopic vesicles consisting of an aqueous core enclosed in a bilayer consisting of cholesterol and one or more nonionic surfactants. They are made of biocompatible, biodegradable, non-toxic, non-immunogenic and non-carcinogenic agents which form closed spherical structures (self assembly vesicles) upon hydration. With high resistance to hydrolytic degradation, niosomes are capable of entrapping many kinds of soluble drugs while exhibiting greater vesicle stability and longer shelf life. In this work, a potential drug delivery system has been designed, synthesized and characterized. For the synthesis of niosomes, a hydration process was developed with varying design parameters such as mass per batch, angle of evaporation, rotation speed of vacuum rotary evaporator and nitrogen flowrate to produce uniform thin film in 50 ml round bottom flask. The rehydration process was developed by varying the choice of solvents (H2O, phosphate buffer solution (PBS) and PBS/5(6)-carboxyfluorescein (CF) as a drug model) and hydrating temperature of below and above gel transition temperature. Lastly, a sonication process to produce unilamellar vesicles was partially optimized based on the particle distribution and the number of vesicles formed with sonication time. As a result of this process, unilamellar and multilamellar vesicles were formed with the combination of different nonionic surfactants (sorbitan monostearate-Span 60, sorbitan monopalmitate-Span40 and sorbitan monolaurate-Span20), cholesterol and an electrostatic stabilizer (dicetyl phosphate). The vesicles were examined using light scattering optical microscopy and UV microscopy. Optical sensing technology (Particle Sizing System) is used to determine the vesicles' size distribution. Gel exclusion chromatography (GEC) is discussed as a method to separate unencapsulated CF while retaining vesicle integrity. Particle Sizing System and luminescence spectrophotometer were used to determine CF encapsulation percentage and leakage. Result: Span 20, Span 40 and Span 60/Niosomes were made with mean particle size of 0.95-0.99 micro (mu)m. Typical concentrations of vesicle per ml/per mass of surfactant used were in the range of 1.46-1.79x108 . Typical encapsulation efficiencies were in the range of 48.8-62.9% for all three Span/Niosome systems. Niosomes were found to be stable for 9 days. The largest vesicles were observed with Span 60 with highest entrapment efficiency as compared to Span 20 and Span 40.

sorbitan monoesters

encapsulation

5(6)-carboxyfluorescein

gel exclusion chromatography

fluorometer

American Studies

Arts and Humanities

Marquage fluorescent des protéines pour étudier les enzymes protéolytiques solubles et immobilisées par la cartographie peptidique électrophorétique

Gan, Shao MIng

06 1900

La cartographie peptidique est une méthode qui permet entre autre d’identifier les modifications post-traductionnelles des protéines. Elle comprend trois étapes : 1) la protéolyse enzymatique, 2) la séparation par électrophorèse capillaire (CE) ou chromatographie en phase liquide à haute performance (HPLC) des fragments peptidiques et 3) l’identification de ces derniers. Cette dernière étape peut se faire par des méthodes photométriques ou par spectrométrie de masse (MS). Au cours de la dernière décennie, les enzymes protéolytiques immobilisées ont acquis une grande popularité parce qu’elles peuvent être réutilisées et permettent une digestion rapide des protéines due à un rapport élevé d’enzyme/substrat. Pour étudier les nouvelles techniques d’immobilisation qui ont été développées dans le laboratoire du Professeur Waldron, la cartographie peptidique par CE est souvent utilisée pour déterminer le nombre total de peptides détectés et leurs abondances. La CE nous permet d’avoir des séparations très efficaces et lorsque couplée à la fluorescence induite par laser (LIF), elle donne des limites de détection qui sont 1000 fois plus basses que celles obtenues avec l’absorbance UV-Vis. Dans la méthode typique, les peptides venant de l’étape 1) sont marqués avec un fluorophore avant l’analyse par CE-LIF. Bien que la sensibilité de détection LIF puisse approcher 10-12 M pour un fluorophore, la réaction de marquage nécessite un analyte dont la concentration est d’au moins 10-7 M, ce qui représente son principal désavantage. Donc, il n’est pas facile d’étudier les enzymes des peptides dérivés après la protéolyse en utilisant la technique CE-LIF si la concentration du substrat protéique initial est inférieure à 10-7 M. Ceci est attribué à la dilution supplémentaire lors de la protéolyse. Alors, afin d’utiliser le CE-LIF pour évaluer l’efficacité de la digestion par enzyme immobilisée à faible concentration de substrat,nous proposons d’utiliser des substrats protéiques marqués de fluorophores pouvant être purifiés et dilués. Trois méthodes de marquage fluorescent de protéine sont décrites dans ce mémoire pour étudier les enzymes solubles et immobilisées. Les fluorophores étudiés pour le marquage de protéine standard incluent le naphtalène-2,3-dicarboxaldéhyde (NDA), la fluorescéine-5-isothiocyanate (FITC) et l’ester de 6-carboxyfluorescéine N-succinimidyl (FAMSE). Le FAMSE est un excellent réactif puisqu’il se conjugue rapidement avec les amines primaires des peptides. Aussi, le substrat marqué est stable dans le temps. Les protéines étudiées étaient l’-lactalbumine (LACT), l’anhydrase carbonique (CA) et l’insuline chaîne B (INB). Les protéines sont digérées à l’aide de la trypsine (T), la chymotrypsine (CT) ou la pepsine (PEP) dans leurs formes solubles ou insolubles. La forme soluble est plus active que celle immobilisée. Cela nous a permis de vérifier que les protéines marquées sont encore reconnues par chaque enzyme. Nous avons comparé les digestions des protéines par différentes enzymes telles la chymotrypsine libre (i.e., soluble), la chymotrypsine immobilisée (i.e., insoluble) par réticulation avec le glutaraldéhyde (GACT) et la chymotrypsine immobilisée sur billes d’agarose en gel (GELCT). Cette dernière était disponible sur le marché. Selon la chymotrypsine utilisée, nos études ont démontré que les cartes peptidiques avaient des différences significatives selon le nombre de pics et leurs intensités correspondantes. De plus, ces études nous ont permis de constater que les digestions effectuées avec l’enzyme immobilisée avaient une bonne reproductibilité. Plusieurs paramètres quantitatifs ont été étudiés afin d’évaluer l’efficacité des méthodes développées. La limite de détection par CE-LIF obtenue était de 3,010-10 M (S/N = 2,7) pour la CA-FAM digérée par GACT et de 2,010-10 M (S/N = 4,3) pour la CA-FAM digérée par la chymotrypsine libre. Nos études ont aussi démontrées que la courbe d’étalonnage était linéaire dans la région de travail (1,0×10-9-1,0×10-6 M) avec un coefficient de corrélation (R2) de 0,9991. / Peptide mapping is a routine method for identifying post-translational modifications of proteins. It involves three steps: 1) enzymatic proteolysis, 2) separation of the peptide fragments by capillary electrophoresis (CE) or high performance liquid chromatography (HPLC), 3) identification of the peptide fragments by photometric methods or mass spectrometry (MS). During the past decade, immobilized enzymes for proteolysis have been gaining in popularity because they can be reused and they provide fast protein digestion due to the high ratio of enzyme-to-substrate. In order to study new immobilization techniques developed in the Waldron laboratory, peptide mapping by CE is frequently used, where the total number of peptides detected and their abundance are related to enzymatic activity. CE allows very high resolution separations and, when coupled to laser-induced fluorescence (LIF), provides excellent detection limits that are 1000 times lower than with UV-Vis absorbance. In the typical method, the peptides produced in step 1) above are derivatized with a fluorophore before separation by CE-LIF. Although the detection sensitivity of LIF can approach 10 12 M for a highly efficient fluorophore, a major disadvantage is that the derivatization reaction requires analyte concentrations to be approx. 10 7 M or higher. Therefore, it is not feasible to study enzymes using CE-LIF of the peptides derivatized after proteolysis if the initial protein substrate concentration is <10-7 M because additional dilution occurs during proteolysis. Instead, to take advantage of CE-LIF to evaluate the efficiency of immobilized enzyme digestion of low concentrations of substrate, we propose using fluorescently derivatized protein substrates that can be purified then diluted. Three methods for conjugating fluorophore to protein were investigated in this work as a means to study both soluble and immobilized enzymes. The fluorophores studied for derivatization of protein standards included naphthalene-2,3-dicarboxaldehyde (NDA), fluoresceine-5-isothiocyanate (FITC) and 6-carboxyfluorescein N-succinimide ester (FAMSE). The FAMSE was found to be an excellent reagent that conjugates quickly with primary amines and the derivatized substrate was stable over time. The studied substrates were -lactalbumin (LACT), carbonic anhydrase (CA) and insulin chain-B (INB). The CE-LIF peptide maps were generated from digestion of the fluorescently derivatized substrates by trypsin (T), chymotrypsin (CT) or pepsin (PEP), either in soluble or insoluble forms. The soluble form of an enzyme is more active than the immobilized form and this allowed us to verify that the conjugated proteins were still recognized as substrates by each enzyme. The digestion of the derivatized substrates with different types of chymotrypsin (CT) was compared: free (i.e., soluble) chymotrypsin, chymotrypsin cross-linked with glutaraldehyde (GACT) and chymotrypsin immobilized on agarose gel particles (GELCT), which was available commercially. The study showed that, according to the chymotrypsin used, the peptide map would vary in the number of peaks and their intensities. It also showed that the digestion by immobilized enzymes was quite reproducible. Several quantitative parameters were studied to evaluate the efficacy of the methods. The detection limit of the overall method (CE-LIF peptide mapping of FAM-derivatized protein digested by chymotrypsin) was 3.010-10 M (S/N = 2.7) carbonic anhydrase using insoluble GACT and 2.010-10 M (S/N = 4.3) CA using free chymotrypsin. Our studies also showed that the standard curve was linear in the working region (1.0×10-9-1.0×10-6 M) with a correlation coefficient (R2) of 0.9991.

α-Lactalbumine

Anhydrase carbonique

Insuline chaîne B

Naphtalène-2,3-dicarboxaldéhyde (NDA)

Fluorescéine-5-isothiocyanate (FITC)

Marquage fluorescent

Enzymes immobilisées

Glutaraldéhyde (GA)

Cartographie peptidique

Électrophorèse capillaire (CE)

Fluorescence induite par laser (LIF)

α-Lactalbumin

Carbonic anhydrase

Insulin chain B

Naphthalene-2,3-dicarboxaldehyde (NDA)

Fluorescein-5-isothiocyanate (FITC)

6-carboxyfluorescein

Fluorescent conjugation

Immobilized enzymes

Glutaraldehyde (GA)

Peptide mapping

Marquage fluorescent des protéines pour étudier les enzymes protéolytiques solubles et immobilisées par la cartographie peptidique électrophorétique

Gan, Shao MIng

06 1900

No description available.

α-Lactalbumine

Anhydrase carbonique

Insuline chaîne B

Naphtalène-2,3-dicarboxaldéhyde (NDA)

Fluorescéine-5-isothiocyanate (FITC)

Marquage fluorescent

Enzymes immobilisées

Glutaraldéhyde (GA)

Cartographie peptidique

Électrophorèse capillaire (CE)

Fluorescence induite par laser (LIF)

α-Lactalbumin

Carbonic anhydrase

Insulin chain B

Naphthalene-2,3-dicarboxaldehyde (NDA)

Fluorescein-5-isothiocyanate (FITC)

6-carboxyfluorescein

Fluorescent conjugation

Immobilized enzymes

Glutaraldehyde (GA)

Peptide mapping