Electro-fluorescence studies of dye, drug and carcinogen binding to DNA and clay minerals

Windsor, Stuart Andrew

January 1996

No description available.

539.7

Fluorescence anisotropy near-field scanning optical microscopy (FANSOM) : a new technique for biological microviscometry /

Reitz, Frederick B.

January 2001

Thesis (Ph. D.)--University of Washington, 2001. / Vita. Includes bibliographical references (leaves 89-94).

Development of a Fluorescence Polarization Assay for Influenza Polymerase Acidic Protein Inhibitors

Kozurek, Grace

11 August 2022

No description available.

Biochemistry

Chemistry

fluorescence polarization

assay development

polymerase acidic protein

influenza

Testing BCL2A1 Small Molecule Inhibitors in Fluorescence Polarization Assays

Ismail, Jaidaa

04 November 2020

No description available.

Immunology

BCL2

BCL2A1

BFL-1

Apoptosis

fluorescence polarization

drug discovery

Homo-FRET Imaging of CEACAM1 in Living Cells using Total Internal Reflection Fluorescence Polarization Microscopy

Lo, Jocelyn

20 November 2012

Carcinoembryonic antigen-related cell adhesion molecule 1 (CEACAM1) undergoes homotypic and heterotypic cis- and trans- interactions that regulate processes including metabolism, immune response, and tumorigenesis. To better understand and eventually control CEACAM1’s numerous roles, we characterized the localization, homotypic cis-oligomerization, and regulation of CEACAM1 at the molecular scale using steady-state TIRFPM homo-FRET imaging in living cells. We established the anisotropy sensitivity of our TIRFPM platform using Venus monomers and dimers, which had significantly different anisotropy values. Heterogeneously distributed across the plasma membrane, CEACAM1-4L-EYFP was a mixture of monomers and oligomers, with a slightly more monomeric population at the high intensity regions. In addition, perturbation with ionomycin or α-CEA pAb increased CEACAM1 monomers, potentially in a localized manner. Although limited in detecting any anisotropy differences between CEACAM1-4L-EYFP and monomeric G432,436L-CEACAM1-4L-EYFP populations, TIRFPM homo-FRET imaging can be a useful tool for studying membrane protein self-association with proper controls and studies that focus on relative anisotropy changes.

Fluorescence polarization microscopy

CEACAM1

Oligomerization

0541

Homo-FRET Imaging of CEACAM1 in Living Cells using Total Internal Reflection Fluorescence Polarization Microscopy

Lo, Jocelyn

20 November 2012

Carcinoembryonic antigen-related cell adhesion molecule 1 (CEACAM1) undergoes homotypic and heterotypic cis- and trans- interactions that regulate processes including metabolism, immune response, and tumorigenesis. To better understand and eventually control CEACAM1’s numerous roles, we characterized the localization, homotypic cis-oligomerization, and regulation of CEACAM1 at the molecular scale using steady-state TIRFPM homo-FRET imaging in living cells. We established the anisotropy sensitivity of our TIRFPM platform using Venus monomers and dimers, which had significantly different anisotropy values. Heterogeneously distributed across the plasma membrane, CEACAM1-4L-EYFP was a mixture of monomers and oligomers, with a slightly more monomeric population at the high intensity regions. In addition, perturbation with ionomycin or α-CEA pAb increased CEACAM1 monomers, potentially in a localized manner. Although limited in detecting any anisotropy differences between CEACAM1-4L-EYFP and monomeric G432,436L-CEACAM1-4L-EYFP populations, TIRFPM homo-FRET imaging can be a useful tool for studying membrane protein self-association with proper controls and studies that focus on relative anisotropy changes.

Fluorescence polarization microscopy

CEACAM1

Oligomerization

0541

High-throughput assays for biotin protein ligase: a novel antibiotic target.

Ng, Belinda Ling Nah

January 2009

Antibiotics are defined as chemical substances that inhibit or limit the growth of microorganisms. Since the second world war, antibiotics have been widely used to reduce the morbidity and mortality associated with serious bacterial infections caused by organisms such as Staphylococcus aureus. However, it has become increasingly difficult to treat bacterial infections due to the emergence of antibiotic resistant strains. The first clinical case of drug resistant bacteria was observed in S. aureus in 1947, just four years after the mass production of penicillin. Since then, resistance has been reported to every antibiotic ever employed. According to the Centres for Disease Control and Prevention of the United States, more than 70% of hospital-acquired infections show resistance to at least one commonly used antibiotic. Coupled with the paucity of therapeutic agents in the pipeline, there is now an urgent demand for new antibiotics. One of the strategies employed to combat drug resistant bacteria requires new chemical entities that work through novel drug targets for which there is no pre-existing resistance. This thesis focuses on the essential metabolic enzyme biotin protein ligase (BPL) as one such new drug target. BPL is the enzyme responsible for covalently attaching the cofactor biotin prosthetic group onto the biotin-dependent enzymes such as the carboxylases, decarboxylases and transcarboxylases. Enzymatic biotinylation proceeds via a two-step reaction whereby biotinyl-5'-AMP is synthesized from biotin and ATP before the biotin moiety is transferred onto the side chain of one specific lysine present in the active site of the biotin-dependent enzyme. One example of an important biotin-dependent enzyme is acetyl CoA carboxylase (ACC). ACC catalyzes the first committed step in fatty acid biosynthesis. Through genetic studies, it has been demonstrated that BPL activity is essential for bacterial survival. The aim for this project was to develop a convenient, high-throughput assay to measure BPL activity. This assay would permit 1) quantitative kinetic analysis of ligands and inhibitors and 2) screening of compound libraries for new BPL inhibitors. We propose that BPL inhibitors can be developed into new antibiotic agents. The novel BPL assay was developed employing fluorescence polarization (FP). FP is a light based technique which uses plane polarized light for the detection of tumbling motion of fluorescent molecules in solution. As polarization of the emitted light is relative to the apparent molecular mass of the fluorophore, this technique can be use for quantitation of changes in molecular mass of target molecules. This enabled 1) rapid kinetic analysis, 2) a minimal number of handling steps, 3) no washing steps and 4) automation by robotics. A first generation assay was developed for Escherichia coli BPL using peptide 85-11 that has been shown to be a convenient substrate. Following the BPL reaction, biotinylated peptides will form large molecular mass complexes with avidin. The amount of product could then be quantitated using FP. Here, kinetic analysis of MgATP (Km 0.25 ± 0.01 mM) and biotin (Km 1.45 ± 0.15 μM) binding produced results consistent with published data. We validated this assay with inhibition studies with end products of the BPL reaction, AMP and pyrophosphate, and a compound, biotinol-5'-AMP. Statistical analysis, performed upon both intraassay and interassay results (n = 30), showed the coefficient of variance to be <10% across all data sets. Furthermore, the Z' factors between 0.5 and 0.8 demonstrated the utility of this technology in high-throughput applications. However, the use of peptide 85-11, a substrate specific to E. coli BPL, does limit the application of this methodology to E. coli. In the second generation FP assay, I adapted this technology for S. aureus BPL by employing the biotin domain of S. aureus pyruvate carboxylase. Insertion of a fluorescein label was achieved by first engineering a cysteine residue into the domain by site directed mutagenesis then incubation with fluorescein-5'-maleimide. A series of mutants was created to investigate optimal positioning of the label into the substrate. Furthermore, the minimal size of the functional domain was determined. Our data showed that the placement of the fluorescein label is an important aspect of this project. Using this approach, I identified that a 90 amino acid domain with the label at position 1134 was optimal. Kinetic analysis of ligand binding showed SaBPL had a Km for biotin at 3.29 ± 0.37 μM and Km for MgATP at 66 ± 16.08 μM. This was in good agreement with data obtained from our previous assay measuring ³H-biotin incorporation. Inhibitor studies with pyrophosphate and analogues of biotin and biotinyl-5'-AMP further validated the assay. Various studies have shown cross-species biotinylation activities by a diverse range of BPLs. Therefore, using this methodology with a biotin domain as the substrate potentially provides a convenient assay for all BPLs. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1374330 / Thesis (M.Sc.) -- University of Adelaide, School of Molecular and Biomedical Science, 2009

High-throughput assays for biotin protein ligase: a novel antibiotic target.

Ng, Belinda Ling Nah

January 2009

Antibiotics are defined as chemical substances that inhibit or limit the growth of microorganisms. Since the second world war, antibiotics have been widely used to reduce the morbidity and mortality associated with serious bacterial infections caused by organisms such as Staphylococcus aureus. However, it has become increasingly difficult to treat bacterial infections due to the emergence of antibiotic resistant strains. The first clinical case of drug resistant bacteria was observed in S. aureus in 1947, just four years after the mass production of penicillin. Since then, resistance has been reported to every antibiotic ever employed. According to the Centres for Disease Control and Prevention of the United States, more than 70% of hospital-acquired infections show resistance to at least one commonly used antibiotic. Coupled with the paucity of therapeutic agents in the pipeline, there is now an urgent demand for new antibiotics. One of the strategies employed to combat drug resistant bacteria requires new chemical entities that work through novel drug targets for which there is no pre-existing resistance. This thesis focuses on the essential metabolic enzyme biotin protein ligase (BPL) as one such new drug target. BPL is the enzyme responsible for covalently attaching the cofactor biotin prosthetic group onto the biotin-dependent enzymes such as the carboxylases, decarboxylases and transcarboxylases. Enzymatic biotinylation proceeds via a two-step reaction whereby biotinyl-5'-AMP is synthesized from biotin and ATP before the biotin moiety is transferred onto the side chain of one specific lysine present in the active site of the biotin-dependent enzyme. One example of an important biotin-dependent enzyme is acetyl CoA carboxylase (ACC). ACC catalyzes the first committed step in fatty acid biosynthesis. Through genetic studies, it has been demonstrated that BPL activity is essential for bacterial survival. The aim for this project was to develop a convenient, high-throughput assay to measure BPL activity. This assay would permit 1) quantitative kinetic analysis of ligands and inhibitors and 2) screening of compound libraries for new BPL inhibitors. We propose that BPL inhibitors can be developed into new antibiotic agents. The novel BPL assay was developed employing fluorescence polarization (FP). FP is a light based technique which uses plane polarized light for the detection of tumbling motion of fluorescent molecules in solution. As polarization of the emitted light is relative to the apparent molecular mass of the fluorophore, this technique can be use for quantitation of changes in molecular mass of target molecules. This enabled 1) rapid kinetic analysis, 2) a minimal number of handling steps, 3) no washing steps and 4) automation by robotics. A first generation assay was developed for Escherichia coli BPL using peptide 85-11 that has been shown to be a convenient substrate. Following the BPL reaction, biotinylated peptides will form large molecular mass complexes with avidin. The amount of product could then be quantitated using FP. Here, kinetic analysis of MgATP (Km 0.25 ± 0.01 mM) and biotin (Km 1.45 ± 0.15 μM) binding produced results consistent with published data. We validated this assay with inhibition studies with end products of the BPL reaction, AMP and pyrophosphate, and a compound, biotinol-5'-AMP. Statistical analysis, performed upon both intraassay and interassay results (n = 30), showed the coefficient of variance to be <10% across all data sets. Furthermore, the Z' factors between 0.5 and 0.8 demonstrated the utility of this technology in high-throughput applications. However, the use of peptide 85-11, a substrate specific to E. coli BPL, does limit the application of this methodology to E. coli. In the second generation FP assay, I adapted this technology for S. aureus BPL by employing the biotin domain of S. aureus pyruvate carboxylase. Insertion of a fluorescein label was achieved by first engineering a cysteine residue into the domain by site directed mutagenesis then incubation with fluorescein-5'-maleimide. A series of mutants was created to investigate optimal positioning of the label into the substrate. Furthermore, the minimal size of the functional domain was determined. Our data showed that the placement of the fluorescein label is an important aspect of this project. Using this approach, I identified that a 90 amino acid domain with the label at position 1134 was optimal. Kinetic analysis of ligand binding showed SaBPL had a Km for biotin at 3.29 ± 0.37 μM and Km for MgATP at 66 ± 16.08 μM. This was in good agreement with data obtained from our previous assay measuring ³H-biotin incorporation. Inhibitor studies with pyrophosphate and analogues of biotin and biotinyl-5'-AMP further validated the assay. Various studies have shown cross-species biotinylation activities by a diverse range of BPLs. Therefore, using this methodology with a biotin domain as the substrate potentially provides a convenient assay for all BPLs. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1374330 / Thesis (M.Sc.) -- University of Adelaide, School of Molecular and Biomedical Science, 2009

High-throughput assays for biotin protein ligase: a novel antibiotic target.

Ng, Belinda Ling Nah

January 2009

Antibiotics are defined as chemical substances that inhibit or limit the growth of microorganisms. Since the second world war, antibiotics have been widely used to reduce the morbidity and mortality associated with serious bacterial infections caused by organisms such as Staphylococcus aureus. However, it has become increasingly difficult to treat bacterial infections due to the emergence of antibiotic resistant strains. The first clinical case of drug resistant bacteria was observed in S. aureus in 1947, just four years after the mass production of penicillin. Since then, resistance has been reported to every antibiotic ever employed. According to the Centres for Disease Control and Prevention of the United States, more than 70% of hospital-acquired infections show resistance to at least one commonly used antibiotic. Coupled with the paucity of therapeutic agents in the pipeline, there is now an urgent demand for new antibiotics. One of the strategies employed to combat drug resistant bacteria requires new chemical entities that work through novel drug targets for which there is no pre-existing resistance. This thesis focuses on the essential metabolic enzyme biotin protein ligase (BPL) as one such new drug target. BPL is the enzyme responsible for covalently attaching the cofactor biotin prosthetic group onto the biotin-dependent enzymes such as the carboxylases, decarboxylases and transcarboxylases. Enzymatic biotinylation proceeds via a two-step reaction whereby biotinyl-5'-AMP is synthesized from biotin and ATP before the biotin moiety is transferred onto the side chain of one specific lysine present in the active site of the biotin-dependent enzyme. One example of an important biotin-dependent enzyme is acetyl CoA carboxylase (ACC). ACC catalyzes the first committed step in fatty acid biosynthesis. Through genetic studies, it has been demonstrated that BPL activity is essential for bacterial survival. The aim for this project was to develop a convenient, high-throughput assay to measure BPL activity. This assay would permit 1) quantitative kinetic analysis of ligands and inhibitors and 2) screening of compound libraries for new BPL inhibitors. We propose that BPL inhibitors can be developed into new antibiotic agents. The novel BPL assay was developed employing fluorescence polarization (FP). FP is a light based technique which uses plane polarized light for the detection of tumbling motion of fluorescent molecules in solution. As polarization of the emitted light is relative to the apparent molecular mass of the fluorophore, this technique can be use for quantitation of changes in molecular mass of target molecules. This enabled 1) rapid kinetic analysis, 2) a minimal number of handling steps, 3) no washing steps and 4) automation by robotics. A first generation assay was developed for Escherichia coli BPL using peptide 85-11 that has been shown to be a convenient substrate. Following the BPL reaction, biotinylated peptides will form large molecular mass complexes with avidin. The amount of product could then be quantitated using FP. Here, kinetic analysis of MgATP (Km 0.25 ± 0.01 mM) and biotin (Km 1.45 ± 0.15 μM) binding produced results consistent with published data. We validated this assay with inhibition studies with end products of the BPL reaction, AMP and pyrophosphate, and a compound, biotinol-5'-AMP. Statistical analysis, performed upon both intraassay and interassay results (n = 30), showed the coefficient of variance to be <10% across all data sets. Furthermore, the Z' factors between 0.5 and 0.8 demonstrated the utility of this technology in high-throughput applications. However, the use of peptide 85-11, a substrate specific to E. coli BPL, does limit the application of this methodology to E. coli. In the second generation FP assay, I adapted this technology for S. aureus BPL by employing the biotin domain of S. aureus pyruvate carboxylase. Insertion of a fluorescein label was achieved by first engineering a cysteine residue into the domain by site directed mutagenesis then incubation with fluorescein-5'-maleimide. A series of mutants was created to investigate optimal positioning of the label into the substrate. Furthermore, the minimal size of the functional domain was determined. Our data showed that the placement of the fluorescein label is an important aspect of this project. Using this approach, I identified that a 90 amino acid domain with the label at position 1134 was optimal. Kinetic analysis of ligand binding showed SaBPL had a Km for biotin at 3.29 ± 0.37 μM and Km for MgATP at 66 ± 16.08 μM. This was in good agreement with data obtained from our previous assay measuring ³H-biotin incorporation. Inhibitor studies with pyrophosphate and analogues of biotin and biotinyl-5'-AMP further validated the assay. Various studies have shown cross-species biotinylation activities by a diverse range of BPLs. Therefore, using this methodology with a biotin domain as the substrate potentially provides a convenient assay for all BPLs. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1374330 / Thesis (M.Sc.) -- University of Adelaide, School of Molecular and Biomedical Science, 2009

Antioxidant Capacity, Lipid Peroxidation, and Lipid Composition Changes During Long-Term and Short-Term Thermal Acclimation in Daphnia

Coggins, Bret L., Collins, John W., Holbrook, Kailea J., Yampolsky, Lev Y.

01 December 2017

Examples of phenotypic plasticity—the ability of organisms of identical genotypes to produce different phenotypes in response to the environment—are abundant, but often lack data on the causative physiology and biochemistry. Phenotypes associated with increased protection against or reduced damage from harmful environments may, in fact, be downstream effects of hidden adaptive responses that remain elusive to experimental measurement or be obscured by homeostatic or over-compensatory effects. The freshwater zooplankton crustacean Daphnia drastically increases its heat tolerance as the result of acclimation to high temperatures, an effect often assumed to be based on plastic responses allowing better protection against oxidative stress. Using several geographically distant Daphnia magna genotypes, we demonstrate that the more heat tolerant individuals have a higher total antioxidant capacity (TAC) both in the comparison of heat-acclimated vs. non heat-acclimated females and in the comparison of females to age- and body size-matched males, which show lower heat tolerance than females. However, experimental manipulations of hypothesized antioxidant pathways by either glutathione addition or glutathione synthesis inhibition had no effect on heat tolerance. Lipid peroxidation (LPO), contrary to expectations, did not appear to be a predictive measure of susceptibility to thermal damage: LPO was higher, not lower, in more heat tolerant heat-acclimated individuals after exposure to a lethally high temperature. We hypothesize that LPO may be maintained in Daphnia at a constant level in the absence of acute exposure to elevated temperature and increase as a by-product of a possible protective antioxidant mechanism during such exposure. This conclusion is corroborated by the observed short-term and long-term changes in phospholipid composition that included an increase in fatty acid saturation at 28 °C and up-regulation of certain long-chain polyunsaturated fatty acids. Phospholipid composition was more strongly affected by recently experienced temperature (4-day transfer) than by long-term (2 generations) temperature acclimation. This is consistent with partial loss of thermal tolerance after a short-term switch to a reciprocal temperature. As predicted under the homeoviscous adaptation hypothesis, the more heat tolerant Daphnia showed lower membrane fluidity than their less heat tolerant counterparts, in comparison both between acclimation temperatures and among different genotypes. We conclude that thermal tolerance in Daphnia is influenced by total antioxidant capacity and membrane fluidity at high temperatures, with both effects possibly reflecting changes in phospholipid composition.

acclimation

antioxidants

Daphnia magna

fluorescence polarization

heat tolerance

lipid composition

lipid peroxidation

membrane fluidity

Biological Sciences