Design, synthesis and application of novel light-activated molecular probes

Stanton-Humphreys, Megan

January 2010

Caged compounds are biologically active molecules that are rendered inert by masking an important functionality with a photolabile protecting, ‘caging’, group. The caging group can be removed by irradiation with light to reveal the active compound with restored pharmacological activity with high spatial and temporal control. This technology provides an ideal tool for the study of many chemical, physiological and biological systems. This DPhil dissertation highlights several projects in which caging technology has been employed to address biological problems and questions. The first example of spatially controlled mitochondrial inactivation is reported - a tool for the study of the role of mitochondria in Ca2+ signalling. Caged TRPV1 agonists and antagonists have been developed to probe TRPV1, specifically the location of the agonist-binding site. T cell activation has been controlled with light as a tool to gain insight into the adaptive immune response. Caged sodium channel blockers have been investigated. Wavelength-orthogonal photolysis in a neuronal system has been demonstrated using the neurotransmitters glutamate and GABA - this represents a significant advancement in caging technology. This dissertation also includes investigations into the development of novel caging groups.

571.4

Une approche moléculaire de l'astringence des vins : utilisation de sondes pour l'étude des interactions entre protéines de la salive et polyphénols

Delcambre, Adéline

03 December 2010

L’astringence est une sensation de sécheresse ressentie en bouche lors de la dégustation des vins rouges, qui résulte de la complexation entre les polyphénols du vin et les protéines de la salive, provoquant une diminution de lubrification en bouche. Parmi les protéines salivaires, les protéines riches en prolines (PRP) sont connues pour leur capacité à se lier aux polyphénols et à précipiter avec eux. Une meilleure connaissance de ce phénomène au niveau moléculaire est nécessaire pour le comprendre et le maîtriser. Il a été montré qu’un peptide de quatorze acides aminés, IB714, dont la séquence est conservée au sein des protéines riches en proline, était un mime représentatif des PRP. Un travail préliminaire par spectrométrie de masse résolue en énergie a permis de caractériser les interactions entre des polyphénols et le peptide IB714. Une échelle d’affinité en phase gazeuse a ainsi été déterminée. Cependant, cette méthodologie d’analyse d’un système modèle ne permet pas de s’accommoder de la complexité du vin. C’est pourquoi nous avons conçu une nouvelle stratégie reposant sur l'utilisation de sondes moléculaires immobilisée sur des billes magnétiques. Dans un premier temps nous avons élaboré une sonde peptidique, en greffant le peptide IB714 sur des billes magnétiques portant des fonctions carboxylates. Cette sonde peptidique a ensuite été étudiée avec des polyphénols modèles. Après sédimentation des billes magnétiques, les polyphénols non captés par la sonde ont été dosés par spectrométrie de masse en utilisant un étalon interne. Une échelle d'affinité en phase liquide a été établie de cette manière. Les positions relatives des polyphénols modèles sur cette échelle sont similaires à celles qui ont été établies en phase gazeuse. Dans un second temps, nous avons construit sur le même principe une sonde polyphénolique. Pour cela, un polyphénol modifié chimiquement a été immobilisé sur des billes magnétiques portant des fonctions amines. Cette sonde polyphénolique a été utilisée pour étudier l'interaction avec le peptide IB714. Par ailleurs, pour préparer une étude des interactions entre polyphénols et protéines salivaires avec des mélanges plus complexes que les systèmes modèles, une étude de fractionnement des protéines salivaires a été entreprise, permettant notamment de d’éliminer l’amylase, protéine majoritaire de la salive humaine. De même, un fractionnement d’un vin rouge a été entrepris pour disposer de fractions de tannins caractérisées par spectrométrie de masse. La sonde peptidique est l’outil moléculaire qui offre le plus de perspectives de développement ultérieur. / Astringency is a pucker or dry mouth sensation, typically experimented with red wine tasting, that finds its origin in the complexation of polyphenols with salivary proteins, producing a reduced lubrication of the oral cavity. Among salivary proteins, proline rich proteins (PRPs) are well known for their capacity to bind and precipitate dietary polyphenols. A better knowledge of this phenomenon at the molecular level is required in order to master it. A 14 amino acid stretch from the PRP IB7 has been synthesized and shown to be a representative mimic of PRPs. Previous work by Energy Resolved Mass Spectrometry (ERMS) allowed characterizing the keys parameters of the interactions between these polyphenols and the IB714 probe. An affinity scale in the gas phase was determined in this way. However, the ERMS approach was hardly compatible with the complexity of wine polyphenols, and a validation of the affinity scale in condensed phase was required. Thus, we designed a new strategy relying on the use of molecular probes immobilized on magnetic beads. A peptidic probe was obtained by grafting the synthetic IB714 peptide on magnetic beads bearing carboxylate functions, and used to study its interaction with model polyphenols. After magnetic precipitation of the beads, unbound polyphenols left in the supernatant were quantified by mass spectrometry using an internal standard. An affinity scale in liquid phase was established in this way. Relative positions of model polyphenols on this latter scale were similar to those determined by ERMS. A polyphenolic probe was obtained by grafting a model polyphenol on beads bearing amine functions. This probe has been used to study the interaction with IB714. To prepare further work on more complex mixtures, attempts were made to fractionate human saliva; this allowed eliminating amylase, the major salivary protein. Wine tannins were also fractionated, in order to isolate condensed polyphenols that are characterized by mass spectrometry. The peptidic probe is the molecular tool that offers the best perspectives for future work.

Spectrométrie de masse

Astringence

Protéine de la salive

Polyphénols

Sondes moléculaires

Mass spectrometry

Astringency

Salivary proteins

Polyphenols

Molecular probes

Identification and characterisation of two haplosporidian parasites of oysters in north Western Australia.

dbearham@hotmail.com, Douglas Bearham

January 2008

A cryptic haplosporidian parasite was detected infecting rock oysters from the Montebello Islands in north-western Australia using a PCR targeting the parasite’s small ribosomal subunit gene. The PCR products were cloned and sequenced along with the remaining sections of the parasite’s SSU rRNA gene. Phylogenetic analysis of the sequence generated indicated a Minchinia species (Haplosporidia). The SSU sequence generated was used to develop two in situ hybridisation assays to visualise the parasite in H/E sections as well as a PCR assay to detect the parasite. The molecular assays were assessed for specificity and sensitivity and were then used to compare the parasite to previous haplosporidian parasite infections of pearl oysters. Both assays produced positive results from the infected pearl oysters but not from other closely related haplosporidian species. An SEM and TEM electron microscopy analysis was performed on spores from both parasite species. The spores of the pearl oyster parasite had two spore wall filaments wound around the spore originating for a posterior thickening while the spores of the rock oyster parasite were covered in microtubule-like structures. These data suggests pearl oysters where co-infected with both the Haplosporidium sp. and the Minchinia sp. detected in rock oysters. No evidence of a posterior thickening could be found on the spores of the rock oyster parasite. Attempts to detect the parasite at the previous geographic sites of its detection in pearl oysters resulted in detection of the Minchinia species in tropical oysters in the Kimberley region of Western Australia by in-situ hybridisation.

Parasite

parasitology

pearling

aquaculture

bivalve

Bonamia

In-situ hybridisation

ISH

diagnostics

molecular probes

Discovery and synthesis of bioactive natural product probes from marine systems

Stout, Elizabeth Paige

15 September 2010

Flora and fauna from terrestrial and marine environments provide libraries of natural compounds for drug discovery. The last four decades have seen major advances in ocean exploration that have allowed chemists and biologists to explore previously inaccessible and rare marine organisms. The study of under-explored marine organisms can result in the discovery of structurally novel and unusual natural products with drug potential. Prior to 2005, no natural products had been reported from the Fijian red macroalgae Callophycus serratus or Neurymenia fraxinifolia. As a result of the work described in this thesis and others in the same research group, 33 unique brominated meroditerpenes have been isolated and elucidated alpha-pyrone natural products were discovered from N. fraxinifolia, enriching the natural product library for drug development. Several natural products isolated from C. serratus exhibited sub-micromolar inhibition against the human malaria parasite Plasmodium falciparum, including a drug-resistant strain. Derivatization of the natural product bromophycolide A into fluorescent probes allowed the determination of a non-enzymatic mechanism of action against the human malaria parasite P. falciparum. Through a combination of detailed SAR mapping, molecular fluorescent imaging of live cells, UV-vis spectroscopic analyses, and protein affinity techniques, the mechanism of action of bromophycolide A against P. falciparum was determined to involve inhibition of heme crystallization. These studies identify a new class of natural products that target heme detoxification in both drug-sensitive and drug-resistant P. falciparum and suggest an avenue to circumvent drug resistance.

Confocal microscopy

Fluorescent probes

Antibacterial

Antimalarial

Macroalgae

Natural products

Molecular probes

Marine natural products

Contrast and sensitivity enhanced molecular imaging using photoacoustic nanoamplifiers

Chen, Yun-Sheng, active 2012

12 November 2013

Molecular imaging is an emerging imaging principle which can visually represent the biological processes both spatially and temporally down to the sub-cellular level in vivo. The outcome of this research is expected to have a profound impact on facilitating the early diagnosis of diseases, accelerating the development of new drugs, and improving the efficacy of therapy. In general, molecular imaging highly relies on probes to sense the occurrence of molecular biological events, and to generate signals which could be picked up by diagnostic imaging modalities. The advances in the design of molecular probes not only have equipped traditional anatomical medical imaging with new capabilities but also, in some cases, stimulated developments of new imaging modalities and renaissance of existing medical imaging modalities. One of these is photoacoustic imaging, which as an emerging medical imaging modality, unites the merits from both optical imaging and ultrasound imaging. It shares with optical imaging, that it uses non-ionizing radiation and provides higher contrast and higher sensitivity than ultrasound imaging. Unlike optical imaging, which requires ballistic photons for imaging, photoacoustic imaging requires only diffusive photons to excite the ultrasound signal from the imaging target; therefore, it is capable of imaging much deeper into the tissue. In combination with molecular probes, photoacoustic molecular imaging has been demonstrated by several research groups using various photoacoustic molecular probes. However, the molecular probes used for most of these studies were contrast agents simply adopted from other optical imaging modalities. Our research on photoacoustic contrast agents indicated that the mechanism of photoacoustic signal generation from nanometer-sized contrast agents is distinct from that of optically homogeneous materials, such as tissue. We have discovered that, the amplitude of the photoacoustic signal generated from nano-contrast agents depends not only on the optical absorption of the particles, but more importantly, on the dynamic process of the heat conduction from the nanoparticles to the ambient, and the thermal properties of the surrounding materials. Based on our finding, we explored and further improved the photoacoustic response of the nanoparticles by exploiting the heat conduction process between the nanoparticle and its surrounding materials and by manipulating the excitations. This research allows to create optimized molecular specific contrast enhanced photothermal stable probes which can aid photoacoustic imaging and image guided photothermal cancer therapy. / text

Photoacoustic imaging

Photothermal cancer therapy

Molecular probes

Contrast agents

Bioconjugation

Nanoparticles

Engineered Molecular Probes for Systematic Studies of Cellular Response in Collective Cell Migration

Riahi, Reza

January 2013

The investigation of complex biological processes, such as wound healing, cell migration, cancer cell invasion, and gene regulatory networks can be benefited tremendously by novel biosensing techniques with high stability and spatiotemporal resolution. In particular, molecular probes with qualities including high stability, sensitivity, and specificity are highly sought-after for long-term monitoring of gene expression in individual cells. Among different single-cell analysis techniques oligonucleotide optical probes is a promising detection method to monitor the dynamics of cellular responses. Herein, the design and optimization of double-stranded LNA probes are first investigated. With alternating DNA/LNA monomers for optimizing the stability and specificity, we show that the probe is highly stable in living cells and is capable of detecting changes in gene expression induced by external stimuli. Using dsLNA probes we then demonstrate the novel approaches to monitor the spatiotemporal gene expression response during cell injury. Our results also suggest a potential autoregulatory role of Nrf2 in injury induced EMT. We also show that the signaling level of dsLNA probe can serve as a molecular signature for the leader cells near the wound which allows us to track the behaviors of leader cells during collective cell migration. Finally multimodal GNR-LNA approach is proposed to map spatiotemporal gene expression profile and reveal dynamic characteristics of heat shock response in photothermal operations.

Gene expression

Optical molecular Probes

wound healing assays

Mechanical Engineering

collective cell migration

Development of Auto-Immolative Spacers for Probes of Enzyme Activity

Thörn Seshold, Oliver

27 June 2013

This thesis concerns the design and implementation of novel auto-immolative spacers for use in probes for enzymatic activity in vivo.The first part relates the development and in vitro validation of cyclisation spacers which couple the action of an aminopeptidase to the release of a phenol. The modular three-component fluorogenic probes based on these 1,2-diamine spacers are very robust (halflife > 560 h), but are also rapidly enzymatically processed, and quickly (halftime ~3 min) release an exceptionally photostable, insoluble ESIPT fluorophore. The probes have excellent detection sensitivity relative to current methods (signal to control ratio > 3000:1), and provide the first demonstration of a macroscopically binary off-ON system for phenol-releasing probes of aminopeptidase activity. The probe system may allow the exceptionally sensitive, ESIPT-based molecular imaging of a range of exopeptidases. The spacers may also be applied in off ON peptidase probes of other phenolic fluorophores, to peptidase-specific phenol/alcohol prodrugs for targeted therapy, or more generally in chemical adapter technologies.In the second part, two novel families of auto-immolative elimination/tautomerisation spacers were designed for use in three-component off ON magnetogenic probes sensing glycosidase activity. The first known substrate-spacer designs based on 2-hydroxyfurans and on carbimidates were explored. Notably, 2 furanol glycosides were synthesised in pursuit of high-energy alternatives to quinone methides, and a general method for preparing model carbimidate-bearing ligands for pro-magnetic probes was elaborated.

[CHIM:OTHE] Chemical Sciences/Other

[CHIM:OTHE] Chimie/Autre

Auto-immolative spacers

Molecular probes

Exopeptidases

Glycosidases

Imaging agents

Development of Auto-Immolative Spacers for Probes of Enzyme Activity

Thörn Seshold, Oliver

27 June 2013

This thesis concerns the design and implementation of novel auto-immolative spacers for use in probes for enzymatic activity in vivo.The first part relates the development and in vitro validation of cyclisation spacers which couple the action of an aminopeptidase to the release of a phenol. The modular three-component fluorogenic probes based on these 1,2-diamine spacers are very robust (halflife > 560 h), but are also rapidly enzymatically processed, and quickly (halftime ~3 min) release an exceptionally photostable, insoluble ESIPT fluorophore. The probes have excellent detection sensitivity relative to current methods (signal to control ratio > 3000:1), and provide the first demonstration of a macroscopically binary off-ON system for phenol-releasing probes of aminopeptidase activity. The probe system may allow the exceptionally sensitive, ESIPT-based molecular imaging of a range of exopeptidases. The spacers may also be applied in off ON peptidase probes of other phenolic fluorophores, to peptidase-specific phenol/alcohol prodrugs for targeted therapy, or more generally in chemical adapter technologies.In the second part, two novel families of auto-immolative elimination/tautomerisation spacers were designed for use in three-component off ON magnetogenic probes sensing glycosidase activity. The first known substrate-spacer designs based on 2-hydroxyfurans and on carbimidates were explored. Notably, 2 furanol glycosides were synthesised in pursuit of high-energy alternatives to quinone methides, and a general method for preparing model carbimidate-bearing ligands for pro-magnetic probes was elaborated.

[CHIM:OTHE] Chemical Sciences/Other

[CHIM:OTHE] Chimie/Autre

Auto-immolative spacers

Molecular probes

Exopeptidases

Glycosidases

Imaging agents

Development of androgen receptor messenger RNA targeted molecular beacons for use in the study of prostate cancer progression

Glick, Cindy Jennifer

31 July 2008

Messenger RNA (mRNA) posttranscriptional regulation has been implicated in the development and/or progression of several diseases including many types of cancer, rheumatoid arthritis, vascular disease, and Alzheimer's disease. Differential regulation of Androgen Receptor (AR) mRNA has been associated specifically with prostate cancer progression. In this thesis, molecular beacons were developed to allow for the detection of the expression and localization of AR mRNA in live prostate cancer cells. These beacons were then applied as a tool for studying how AR mRNA regulation is involved in prostate cancer growth and advancement. Two AR mRNA targeted beacons were designed and tested in solution and in live cells to determine their functionality. The beacon-based approach for AR mRNA detection was then optimized through the use of the two beacons in tandem and alteration of their backbone chemistry. A series of validation tests were performed on these beacons, including testing their abilities to: 1) produce a feasible localization pattern, 2) discriminate between AR positive (AR+) and AR negative (AR-) prostate cancer cell lines and 3) follow stimulus-induced changes in AR mRNA expression. Based on these results, a dual chimeric beacon approach was selected to determine the role of AR mRNA regulation in two systems that represent important stages in prostate cancer growth and progression: 1) hormone stimulation of androgen-dependent prostate cancer cells and 2) progression of androgen-dependent prostate cancer cells to the androgen-independent state. Our results suggest that changes in AR mRNA expression, organization, and localization may be indicative of molecular mechanisms involved in these critical transitions associated with prostate cancer progression. Taken together, this work provides a feasibility study for visualizing changes in AR mRNA state as a diagnostic measure for evaluating the aggressiveness of the disease and demonstrates the possible utility of therapeutically targeting AR mRNA regulation in order to prevent prostate cancer advancement.

Prostate cancer

Molecular beacons

Androgen receptor

MRNA

Prostate Cancer

Messenger RNA

Molecular probes

Development of cancer diagnostics using nanoparticles and amphiphilic polymers

Rhyner, Matthew N.

January 2008

Thesis (Ph. D.)--Biomedical Engineering, Georgia Institute of Technology, 2008. / Committee Chair: Nie, Shuming; Committee Member: Bao, Gang; Committee Member: Chung, Leland; Committee Member: Murthy, Niren; Committee Member: Prausnitz, Mark.