Mutations in atpG affect postranscriptional expression of pckA in <i>Escherichia coli</i>

Permala-Booth, Jasnehta

05 May 2008

Prokaryotic cells such as Escherichia coli use glucose as their preferred carbon source. In the absence of glucose, these cells resort to other sources to generate glucose and this process of de novo synthesis of glucose is termed gluconeogenesis. Phosphoenolpyruvate carboxykinase (Pck) is one of the three enzymes important in regulating gluconeogenesis. It converts oxaloacetic acid (OAA) from the Krebs cycle to phosphoenolpyruvate (PEP), a glycolytic intermediate. The Pck structural gene (pckA) is regulated by catabolite repression. There is a 100-fold induction of pckA-lacZ fusions at the onset of stationary phase concurrent with induction of glycogen synthesis. Mutants affecting the expression of pckA were analysed to shed some light on the mechanism of its genetic regulation.<p>Spontaneous mutants isolated with Pck- (lack of PEP carboxykinase activity) and Suc- (inability to utilise succinate as carbon source) phenotypes were previously characterised as atpG mutants defective in the ã subunit of ATP synthase.<p>In this work we find by reverse transcriptase and real time quantitative PCR that levels of pckA mRNA are normal in the atpG mutants and that the defects in expression of pckA are therefore likely at the level of translation, protein assembly and/or protein degradation. As expected, ATP synthase activity and proton pumping in inside-out membrane vesicles were defective in these atpG mutants. It is likely that one of these defects is affecting regulation or expression of the pckA gene. It was observed that atpG mutants were defective in calcium-dependent transformation although they could be made competent for electroporation. The atpG mutants were also defective for growth of P1 bacteriophage although they could serve as recipients for P1-dependent generalised transduction. These latter phenotypes are also likely due to defects in energy metabolism.

fluorescence quenching

real time reverse transcriptase PCR

gene regulation

PEP carboxykinase

atpG mutants

ATP synthase

gluconeogenesis

Escherichia coli

genetics

acridine orange

Mutations in atpG affect postranscriptional expression of pckA in <i>Escherichia coli</i>

Permala-Booth, Jasnehta

05 May 2008

Prokaryotic cells such as Escherichia coli use glucose as their preferred carbon source. In the absence of glucose, these cells resort to other sources to generate glucose and this process of de novo synthesis of glucose is termed gluconeogenesis. Phosphoenolpyruvate carboxykinase (Pck) is one of the three enzymes important in regulating gluconeogenesis. It converts oxaloacetic acid (OAA) from the Krebs cycle to phosphoenolpyruvate (PEP), a glycolytic intermediate. The Pck structural gene (pckA) is regulated by catabolite repression. There is a 100-fold induction of pckA-lacZ fusions at the onset of stationary phase concurrent with induction of glycogen synthesis. Mutants affecting the expression of pckA were analysed to shed some light on the mechanism of its genetic regulation.<p>Spontaneous mutants isolated with Pck- (lack of PEP carboxykinase activity) and Suc- (inability to utilise succinate as carbon source) phenotypes were previously characterised as atpG mutants defective in the ã subunit of ATP synthase.<p>In this work we find by reverse transcriptase and real time quantitative PCR that levels of pckA mRNA are normal in the atpG mutants and that the defects in expression of pckA are therefore likely at the level of translation, protein assembly and/or protein degradation. As expected, ATP synthase activity and proton pumping in inside-out membrane vesicles were defective in these atpG mutants. It is likely that one of these defects is affecting regulation or expression of the pckA gene. It was observed that atpG mutants were defective in calcium-dependent transformation although they could be made competent for electroporation. The atpG mutants were also defective for growth of P1 bacteriophage although they could serve as recipients for P1-dependent generalised transduction. These latter phenotypes are also likely due to defects in energy metabolism.

fluorescence quenching

real time reverse transcriptase PCR

gene regulation

PEP carboxykinase

atpG mutants

ATP synthase

gluconeogenesis

Escherichia coli

genetics

acridine orange

The Study of Binding Behaviors between Dissolved Organic Matter and Polycyclic Aromatic Compounds

Hsieh, Ping-Chieh

23 June 2011

Polycyclic aromatic hydrocarbons (PAHs) and nitrogen-containing polycyclic aromatic compound (N-PAC) are widespread toxic pollutants in environments. The fate of PAHs and N-PACs are of great concern because some of these compounds were identified as caricinogenic, mutagenic and teratogenic compounds. As described in literature, dissolved organic matter (DOM) is an important factor in control of their fate; however, the binding behaviors between these compounds and DOM are still not fully understood. The binding constants (KDOC) between humic substances and one selected N-PAC, benzo[h]quinoline, were measured at varying pH levels using fluorescence quenching (FQ) method. As fluorescence characteristics of benzo[h]quinoline change with pH, determination required two optimum sets of excitation and emission wavelength pairs. A simple mixing model was proposed and used to eliminate the inherent fluorescence interference between benzo[h]quinoline (BQ) and its protonated form, benzo[h]quinolinium (BQH+), and to deduce Kmix which represents the overall binding as the sum of that for the individual analogs. The characteristics of humic substances, especially their hydrophobicity and aromaticity, established by principal components analysis of structural and elemental compositions, were the main determinants of their binding affinity with both benzo[h]quinoline and benzo[h]quinolinium (KBQ and KBQH+) across a range of pH values. Hydrophobic interaction is likely to control the binding between humic substance and benzo[h]quinoline and benzo[h]quinolinium, in lower and higher pH ranges (pH<3, pH>6). In contrast, cation exchange seems to control on the binding affinity of benzo[h]quinolinium in the middle range of pH. Determination of PAH concentration is quite essential for investigating the fate of PAHs in environments. Microwave-assisted headspace solid-phase microextraction (MA-HS-SPME) with a polydimethylsiloxane/divinylbenzene (PDMS/DVB) fiber was applied as a single step prior to determination of PAH concentrations in water using GC-MS. To optimize the extraction efficiency of PAHs by MA-HS-SPME, the influence of various parameters, including temperature, duration of thermal desorption, microwave irradiation power and duration, and the temperature of the circulating cooling water system, was studied. The proposed method was demonstrated applicable to environmental water samples. In addition, DOM matrix effect did not influence the determination and extraction efficiency of PAHs. Although the proposed simple mixing model can eliminate the fluorescent interference of hydrophobic organic compounds with acid-base pair forms, it is still limited in using for correcting the KDOC measurement of more than two fluorescent compounds simultaneously. A new alternative protocol, complexation-flocculation combined with MA-HS-SPME/GC-MS method, was proposed to determine the binding constants of seleted PAHs to humic substances. The results obtained are comparable with KDOC data reported in literatures. CF-MA-HS-SPME/GC-MS provides some advantages over other methods, such as applicable not limited to fluorescent compounds, faster in determination and capable in measuring varieties of compounds simultaneously.

complexation-flocculation

headspace solid-phase microextraction

polycyclic aromatic hydrocarbons

microwave irradiation

fluorescence quenching

binding constant

dissolved organic matters

Φωτοφυσική μελέτη οργανικών χρωστικών και διερεύνηση μηχανισμών απόσβεσης και μεταφοράς ενέργειας

Παπαχρήστου, Νικολίτσα

13 May 2015

Στην παρούσα Ειδική Ερευνητική Εργασία μελετόνται οι φωτοφυσικές ιδιότητες γνωστών χρωμοφόρων μορίων. Συγκεκριμένα μελετάται η Coumarin 30, η Fluorescein Isothiocyanate και η Dichlorofluorescein, τόσο με φασματοσκοπία σταθερής κατάστασης όσο και με φασματοσκοπία χρονικής ανάλυσης μέσω της τεχνικής Time Correlated Single Photon Counting. Η διερεύνηση γίνεται με τα μόρια αυτά να βρίσκονται σε μορφή διαλυμάτων με στόχο τον προσδιορισμό της συμπεριφοράς τους όταν αυτά βρισκονται σε διαφορετικά περιβάλλοντα (διαλύτες). Επιπλέον ερευνώνται οι αλληλεπιδράσεις των μορίων αυτών μέσω της φασματοσκοπίας σταθερής κατάστασης και χρονικής ανάλυσης όταν βρίσκονται σε μορφή μειγμάτων. / In this Master Thesis, the phophysical properties of chromophrores are investigated. Specifically, Coumarin 30, Fluorescein Isothiocyanate and Dichlorofluorescein are studied with steady – state spectroscopy as well as with time – resolved spectroscopy via the technique of Time Correlated Single Photon Counting. The study of these molecules focuses also on solvent – solute effects. Finally, interactions between them are also studied through steady – state spectroscopy and time resolved spectroscopy.

Κουμαρίνη 30

Φλουρεσκίνη

Απόσβεση φθορισμού

Μεταφορά ενέργειας

535.35

Steady state spectroscopy

Time resolved spectroscopy

Coumarin 30

Fluorescein

Fluorescence quenching

Energy transfer

Nanostructures d'ADN supportées sur billes magnétiques de nouveaux outils senseurs des systèmes de réparation de l'ADN

Gines, Guillaume

04 October 2013

Notre génome, véritable mode d'emploi de chaque cellule et organisme, est constamment menacé par de multiples agents endogènes ou exogènes qui endommagent la biomolécule d'ADN. Ces lésions résultantes, de nature diverse, sont notamment impliquées dans les processus de vieillissement cellulaire, de cancérogénèse et de mort cellulaire. Afin de contrer ces effets néfastes, les organismes ont développé différents systèmes de réparation de l'ADN capables de prendre en charge spécifiquement chaque type de dommages. Parmi ces voies métaboliques, la réparation par excision de base (BER) répare chaque jour des dizaines de milliers de dommages, incluant les bases alkylées, oxydées ou désaminées, les sites abasiques ou encore certaines cassures de brin. Dans le présent travail, nous exposons la mise au point d'un nouveau biocapteur pour la détection des activités enzymatiques du BER. L'outil se caractérise par un set de sondes nucléiques autocomplémentaires, fluorescentes ou pro-fluorescentes, immobilisées sur microbilles paramagnétiques. Chaque sonde est modifiée par l'introduction sélective d'une lésion, substrat d'une activité enzymatique ciblée (ADN N-glycosylase, AP-endonucléase). L'activité d'excision/incision de la lésion, conduit à la coupure de la sonde et à la déshybridation de la structure. L'analyse et la quantification du clivage spécifique est réalisée en fluorescence, soit à partir du surnageant par spectrofluorimétrie, soit des billes par cytométrie en flux. Ce dispositif permet la détection multiplexée des activités enzymatiques de protéines purifiées ou au sein d'extraits nucléaires. Egalement, des applications dans le criblage d'inhibiteurs de la réparation de l'ADN sont envisageables dans le cadre de recherches pré-cliniques. L'adaptation de ces tests in vitro à la détection de la réparation de l'ADN in cellulo a fait l'objet de développements préliminaires.

Réparation de l'ADN

Biocapteurs

Billes magnétiques

Fluorescence/quenching

Cytométrie en flux

Multiplexage

The Effect of Salts on the Conformational Stability of Proteins

Beauchamp, David L

13 April 2012

It has long been observed that salts affect proteins in a variety of ways, yet comprehensive explanations for different salt effects are still lacking. In the work presented here, the effect of salts on proteins has been investigated through three different effects: the hydrophobic effect; their conformational stability; the hydrogen bonding network of water in a protein’s hydration shell. UV-vis absorbance and fluorescence spectroscopy were used to monitor changes in two model systems, the phenol-acetate contact pair and the model enzyme ribonuclease t1. It was shown that salts affect the hydrophobicity of the contact pair according to their charge density, induced image charges play an important role in the observed salt-induced increase of ribonuclease t1 stability, and that salts affect ribonuclease t1 activity through modulation of the hydrogen bonds of water in the enzyme’s hydration shell. This work contributes a greater understanding of the effect of salts on proteins.

Hydrophobic effect

Fluorescence quenching

Salt effects

Protein folding

Induced point-image charges

Kirkwood interactions

Continuum model

Hydrogen bonding

Water-water interactions

Charge density

Enzymatic activity

The Effect of Salts on the Conformational Stability of Proteins

Beauchamp, David L

13 April 2012

It has long been observed that salts affect proteins in a variety of ways, yet comprehensive explanations for different salt effects are still lacking. In the work presented here, the effect of salts on proteins has been investigated through three different effects: the hydrophobic effect; their conformational stability; the hydrogen bonding network of water in a protein’s hydration shell. UV-vis absorbance and fluorescence spectroscopy were used to monitor changes in two model systems, the phenol-acetate contact pair and the model enzyme ribonuclease t1. It was shown that salts affect the hydrophobicity of the contact pair according to their charge density, induced image charges play an important role in the observed salt-induced increase of ribonuclease t1 stability, and that salts affect ribonuclease t1 activity through modulation of the hydrogen bonds of water in the enzyme’s hydration shell. This work contributes a greater understanding of the effect of salts on proteins.

Hydrophobic effect

Fluorescence quenching

Salt effects

Contiuum model

Protein folding

Induced point-image charges

Kirkwood interactions

Continuum model

Hydrogen bonding

Water-water interactions

Charge density

Enzymatic activity

Advanced optical techniques to study biomolecular aggregation processes

Quinn, Steven D.

January 2014

Alzheimer's disease (AD) is characterised by a series of biomolecular aggregation events, which include the formation of neurotoxic protein structures composed of the β-amyloid (Aβ) peptide. In this thesis, fluorescence self-quenching (FSQ) between fluorescently-labelled peptides is introduced as a strategy for detecting and characterizing Aβ aggregates in solution, and for overcoming limitations associated with conventional methods. Using a combination of steady-state, picosecond time-resolved fluorescence and transmission electron microscopy, the fluorescence response of HiLyte Fluor 555-labelled Aβ peptides is characterised to demonstrate that Aβ self-assembly organizes the covalently attached probes in close proximity to trigger the self-quenching sensing process over a broad range of conditions. Importantly, N-terminal tagging of β-amyloid peptides is shown to not alter the self-assembly kinetics or the resulting aggregated structures. When performed in Förster resonance energy transfer (FRET) format, this method becomes a ratiometric platform to gain insights into amyloid structure and for standardizing in vitro studies of amyloid self-assembly. The ability of FSQ-based methods to monitor the inhibition of Aβ aggregation by model test compounds including the small heat shock protein (Hsp), the amyloid-binding alcohol dehydrogenase protein (ABAD) and bovine serum albumin (BSA) is also demonstrated. Given that Aβ is formed within the cell membrane and is known to induce its disruption, sophisticated single-molecule fluorescence spectroscopy methods were developed to quantify membrane dynamics induced by the presence of disrupting agents, such as Aβ and detergents. The solubilisation dynamics of single liposomes induced by the non-ionic surfactant Triton-X 100 (TX-100) were studied in real-time. Using this approach, the swelling and permeabilization steps of the solubilisation process were unambiguously separated within single FRET trajectories, and their kinetic details as a function of Triton-X 100 and presence of cholesterol within the membrane structure were examined. Finally, single-molecule stepwise-photobleaching techniques were employed to study the effect of Aβ oligomers interacting with supported-lipid bilayers, establishing a platform from which to investigate how the presence of a membrane layer affects Aβ oligomerization at the level of individual molecules. Overall, the fluorescence-based strategies for amyloid- and liposome-sensing presented in this work bridges the gap between current morphology-specific techniques and highly-specialized single-molecule methods to provide a biophysical toolbox to investigate the changes in structure, size and molecular interactions accompanying the amyloid aggregation pathway and for the screening of novel therapeutic and diagnostic agents.

572

Vliv chemické modifikace huminových kyselin na jejich interakce s organickými ionty / Effect of chemical modification of humic acids on their interactions with organic ions

Fryšová, Eva

January 2017

This master thesis deals with the interaction of humic acids with organic ions and effect of chemical modification of humic acids on this interaction. Rhodamine 6G was used as a model organic ion. The interaction were studied by fluorescence quenching, dialysis in diffusion cells and differential UV-VIS spectroscopy. Results showed that the bond between the reactants was not primarily dependent on carboxylic functional groups of humic acids. Fluorescence experiments indicated static quenching mechanism and differential UV-VIS spectroscopy demonstrated the existence of - interactions.

Biochemical applications of DsRed-monomer utilizing fluorescence and metal-binding affinity

Goulding, Ann Marie

09 March 2011

Indiana University-Purdue University Indianapolis (IUPUI) / The discovery and isolation of naturally occurring fluorescent proteins, FPs, have provided much needed tools for molecular and cellular level studies. Specifically the cloning of green fluorescent protein, GFP, revolutionized the field of biotechnology and biochemical research. Recently, a red fluorescent protein, DsRed, isolated from the Discosoma coral has further expanded the pallet of available fluorescent tools. DsRed shares only 23 % amino acid sequence homology with GFP, however the X-ray crystal structures of the two proteins are nearly identical. DsRed has been subjected to a number of mutagenesis studies, which have been found to offer improved physical and spectral characteristics. One such mutant, DsRed-Monomer, with a total of 45 amino acid substitutions in native DsRed, has shown improved fluorescence characteristics without the toxic oligomerization seen for the native protein. In our laboratory, we have demonstrated that DsRed proteins have a unique and selective copper-binding affinity, which results in fluorescence quenching. This copper-binding property was utilized in the purification of DsRed proteins using copper-bound affinity columns. The work presented here has explored the mechanism of copper-binding by DsRed-Monomer using binding studies, molecular biology, and other biochemical techniques. Another focus of this thesis work was to demonstrate the applications of DsRed-Monomer in biochemical studies based on the copper-binding affinity and fluorescence properties of the protein. To achieve this, we have focused on genetic fusions of DsRed-Monomer with peptides and proteins. The work with these fusions have demonstrated the feasibility of using DsRed-Monomer as a dual functional tag, as both an affinity tag and as a label in the development of a fluorescence assay to detect a ligand of interest. Further, a complex between DsRed-Monomer-bait peptide/protein fusion and an interacting protein has been isolated taking advantage of the copper-binding affinity of DsRed-Monomer. We have also demonstrated the use of non-natural amino acid analogues, incorporated into the fluorophore of DsRed-Monomer, as a tool for varying the spectral properties of the protein. These mutations demonstrated not only shifted fluorescence emission compared to the native protein, but also improved extinction coefficients and quantum yields.

fluorescent protein labeling

non-natural mutagenesis

ligand fishing

protein-protein interactions

fluorescence quenching

metal-binding affinity

red fluorescent protein

Proteins -- Affinity labeling

Protein binding

Mutagenesis

Protein-protein interactions