Global ETD Search

51	Nanomechanics of Barnacle Proteins and Multicomponent Lipid Bilayers Studied by Atomic Force Microscopy Sullan, Ruby May Arana 23 February 2011 (has links) Owing to atomic force microscopy’s (AFM) high-resolution in both imaging and force spectroscopy, it is very successful in probing not only structures, but also nanomechanics of biological samples in solution. In this thesis, the nanomechanical properties of lipid bilayers of biological relevance and proteins of the barnacle adhesive were examined using AFM indentation, AFM-based force mapping, and single-molecule pulling experiments. Through high-resolution AFM-based force mapping, the self-organized structures exhibited in phase-segregated supported lipid bilayers consisting of dioleoylphosphatidylcholine / egg sphingomyelin / cholesterol (DEC) in the absence and presence of ceramide (DEC-Ceramide) were directly correlated with their breakthrough forces, elastic moduli, adhesion, and bilayer thickness. Results were presented as two-dimensional visual maps. The highly stable ceramide-enriched domains in DEC-Ceramide bilayers and the effect of different levels of cholesterol as well as of diblock copolymers, on the nanomechanical stability of the model systems studied were further examined. For the proteins of the barnacle adhesive, scanning electron microscopy (SEM), Fourier transform infrared (FTIR) spectroscopy, and chemical staining with amyloid-selective dyes, in addition to AFM imaging, indentation, and pulling experiments were performed to study the structure and nanomechanics of the polymerized barnacle glue. Nanoscale structures exhibiting rod-shaped, globular, and irregularly shaped morphologies were observed in the bulk barnacle cement by AFM. SEM coupled with energy dispersive x-ray (EDX) makes evident the organic nature of the rod-shaped nanoscale structures while FTIR spectroscopy on the bulk cement gave signatures of β-sheet and random coil conformations. Indentation data yielded higher elastic moduli for the rod-shaped structures as compared to the other structures in the bulk cement. Single molecule AFM force-extension curves on the matrix of the bulk cement often exhibited a periodic sawtooth-like profile, observed in both extend and retract portions of the force curve. Rod-shaped structures stained with amyloid protein-selective dyes (Congo Red and Thioflavin-T) revealed that about 5% of the bulk cement are amyloids. multicomponent lipid bilayers barnacle proteins nanomechanics force mapping AFM force spectroscopy raft mimics 0786 0494 0487
52	Quantitative Evaluation of Semiconductor Nanocrystals as Contrast Agents for Fluorescence Molecular Imaging Roy, Mathieu 31 August 2012 (has links) Fluorescence molecular imaging has been triggering interest in the scientific community for the last decade due to its great potential for improved early cancer detection and image-guided treatment. Semiconductor nanoparticles, also known as quantum dots, have been identified as potential contrast agents for molecular imaging, but there is a lack of quantitative contrast optimization studies that would enable precise and robust dosimetry calculations. These calculations are crucial to determine the feasibility, risk and cost of any contrast-enhanced clinical imaging procedure. This thesis presents a first attempt at developing a quantitative dosimetry framework for quantum dot-based contrast-enhanced fluorescence molecular imaging, by combining novel experimental methods and validated mathematical models. Three studies were completed to develop the dosimetry framework. In the first study, we design a novel homogenized optical tissue phantom approach to investigate with precision the effects of various photophysical parameters, such as the excitation and emission wavelengths, tissue absorption and scattering coefficient spectra, tissue autofluorescence spectra, target fluorescence spectra and target depth, on the detected contrast. In the second study, we use the approach to investigate the influence of tissue optical absorption and scattering on contrast behavior for various ex vivo tissue samples, and develop performance metrics to quantify the optimization results. In the third study, we perform vascular fluorescence contrast-enhanced imaging in the dorsal skinfold window chamber mouse model to investigate the effects of pharmacokinetics, blood absorption, vessel diameter and injected dose on the detected contrast. We also describe the relationship between the injected volume and vascular contrast, and transfer the performance metrics developed previously to estimate the minimum injection dose under various conditions. These studies are expected to serve as a stepping stone to further develop contrast optimization and dosimetry models for the emerging field of fluorescence molecular imaging. Fluorescence Quantum Dots Optimization Dosimetry Endoscopy Biophotonics Contrast Nanotechnology 0760 0786 0752
53	Quantitative Evaluation of Semiconductor Nanocrystals as Contrast Agents for Fluorescence Molecular Imaging Roy, Mathieu 31 August 2012 (has links) Fluorescence molecular imaging has been triggering interest in the scientific community for the last decade due to its great potential for improved early cancer detection and image-guided treatment. Semiconductor nanoparticles, also known as quantum dots, have been identified as potential contrast agents for molecular imaging, but there is a lack of quantitative contrast optimization studies that would enable precise and robust dosimetry calculations. These calculations are crucial to determine the feasibility, risk and cost of any contrast-enhanced clinical imaging procedure. This thesis presents a first attempt at developing a quantitative dosimetry framework for quantum dot-based contrast-enhanced fluorescence molecular imaging, by combining novel experimental methods and validated mathematical models. Three studies were completed to develop the dosimetry framework. In the first study, we design a novel homogenized optical tissue phantom approach to investigate with precision the effects of various photophysical parameters, such as the excitation and emission wavelengths, tissue absorption and scattering coefficient spectra, tissue autofluorescence spectra, target fluorescence spectra and target depth, on the detected contrast. In the second study, we use the approach to investigate the influence of tissue optical absorption and scattering on contrast behavior for various ex vivo tissue samples, and develop performance metrics to quantify the optimization results. In the third study, we perform vascular fluorescence contrast-enhanced imaging in the dorsal skinfold window chamber mouse model to investigate the effects of pharmacokinetics, blood absorption, vessel diameter and injected dose on the detected contrast. We also describe the relationship between the injected volume and vascular contrast, and transfer the performance metrics developed previously to estimate the minimum injection dose under various conditions. These studies are expected to serve as a stepping stone to further develop contrast optimization and dosimetry models for the emerging field of fluorescence molecular imaging. Fluorescence Quantum Dots Optimization Dosimetry Endoscopy Biophotonics Contrast Nanotechnology 0760 0786 0752
54	Single Proteins under the Microscope: Conformations, Dynamics and Medicinal Therapies Liu, Baoxu 20 June 2014 (has links) We applied single-molecule fluorescence (SMF) methods to probe the properties of individual fluorescent probes, and to characterize the proteins of interest to which these probes were attached. One remarkable advantage of SMF spectroscopy is the ability to investigate heterogeneous subpopulations of the ensemble, which are buried in ensemble averaging in other measurements. Other advantages include the ability to probe the entire dynamic sequences of a single molecule transitioning between different conformational states. For the purpose of having an extended observation of single molecules, while maintaining the native nanoscale surroundings, we developed an improved vesicle preparation method for encapsulating scarce biological samples. SMF investigations revealed that molecules trapped in vesicles exhibit nearly ideal single-emitter behavior, which therefore recommends the vesicle encapsulation for reproducible and reliable SMF studies. Hyperactive Signal-Transducer-and-Activator-of-Transcription 3 (STAT3) protein contributes significantly to human cancers, such as leukemia and lymphoma. We have proposed a novel therapeutic strategy by designing a cholesterol-based protein membrane anchor (PMA), to tether STAT3 to the cell membrane and thus inhibit unwanted transcription at the cell nucleus. We designed in vitro proof-of-concept experiments by encapsulating STAT3 and PMAs in phospholipid vesicles. The efficiency and the stability of STAT3 anchoring in the lipid membrane were interrogated via quantitative fluorescence imaging and multiparameter SMF spectroscopy. Our in vitro data paved the way for the in vivo demonstration of STAT3 inhibition in live cells, thus demonstrating that PMA-induced protein localization is a conceptually viable therapeutic strategy. The recent discovery of intrinsically disordered proteins (IDPs) highlights important exceptions to the traditional structure-function paradigm. SMF methods are very suited for probing the properties of such highly heterogeneous systems. We studied in detail the effects of electrostatics on the conformational disorder of an IDP protein, Sic1 from yeast, and found that the electrostatic repulsion is a major factor controlling the dimensions of Sic1. Based on our data we also conclude that a rod-like shape seems a better candidate than a random Gaussian chain to describe and predict the behavior of Sic1. Intrinsically Disordered Protein New Cancer Therapies Protein Membrane Anchorage 0752 0786 0760
55	Single Proteins under the Microscope: Conformations, Dynamics and Medicinal Therapies Liu, Baoxu 20 June 2014 (has links) We applied single-molecule fluorescence (SMF) methods to probe the properties of individual fluorescent probes, and to characterize the proteins of interest to which these probes were attached. One remarkable advantage of SMF spectroscopy is the ability to investigate heterogeneous subpopulations of the ensemble, which are buried in ensemble averaging in other measurements. Other advantages include the ability to probe the entire dynamic sequences of a single molecule transitioning between different conformational states. For the purpose of having an extended observation of single molecules, while maintaining the native nanoscale surroundings, we developed an improved vesicle preparation method for encapsulating scarce biological samples. SMF investigations revealed that molecules trapped in vesicles exhibit nearly ideal single-emitter behavior, which therefore recommends the vesicle encapsulation for reproducible and reliable SMF studies. Hyperactive Signal-Transducer-and-Activator-of-Transcription 3 (STAT3) protein contributes significantly to human cancers, such as leukemia and lymphoma. We have proposed a novel therapeutic strategy by designing a cholesterol-based protein membrane anchor (PMA), to tether STAT3 to the cell membrane and thus inhibit unwanted transcription at the cell nucleus. We designed in vitro proof-of-concept experiments by encapsulating STAT3 and PMAs in phospholipid vesicles. The efficiency and the stability of STAT3 anchoring in the lipid membrane were interrogated via quantitative fluorescence imaging and multiparameter SMF spectroscopy. Our in vitro data paved the way for the in vivo demonstration of STAT3 inhibition in live cells, thus demonstrating that PMA-induced protein localization is a conceptually viable therapeutic strategy. The recent discovery of intrinsically disordered proteins (IDPs) highlights important exceptions to the traditional structure-function paradigm. SMF methods are very suited for probing the properties of such highly heterogeneous systems. We studied in detail the effects of electrostatics on the conformational disorder of an IDP protein, Sic1 from yeast, and found that the electrostatic repulsion is a major factor controlling the dimensions of Sic1. Based on our data we also conclude that a rod-like shape seems a better candidate than a random Gaussian chain to describe and predict the behavior of Sic1. Intrinsically Disordered Protein New Cancer Therapies Protein Membrane Anchorage 0752 0786 0760
56	Detergents as Membrane-mimetic Media for Structural Characterization of Membrane Proteins Tulumello, David 31 August 2012 (has links) Membrane proteins are essential cellular components, responsible for a wide variety of biological functions. In order to better understand such aspects of cell activity, researchers have pursued detailed structural analysis of this class of proteins. Because of the complexities in isolating and studying membrane proteins in their native environment, detergents are often employed as a membrane mimetic media. This thesis examines several features of transmembrane (TM) protein structure and folding in detergents through which we are able to gain insights into membrane protein folding, as well as explore the suitability of detergents as membrane-mimetic environments. We first compare the helix-helix association of a series of model TM sequences in a native bilayer to the corresponding association in a detergent environment. We find that while various classes of helix-helix interaction motifs are preserved in detergents, alterations in detergent solvation may, in turn, lead to altered association affinity. We further explore this phenomenon through investigation of the consequences of the insertion of a strongly polar residue into a TM segment. In these studies we find a correlation between sequence-dependent alterations in detergent solvation and predicted in vivo folding. We also extend such analyses to a variety of detergents and native TM segments, finding that native secondary structure, as it occurs in the context of a full-length protein, is generally well preserved in a variety of detergents. Finally, we assess the determinants of membrane protein folding using two-transmembrane segment constructs, in the process optimizing expression, production and characterization techniques for a diverse range of transmembrane protein sequences. Overall this thesis finds that, detergents are capable of solubilizing membrane proteins in a form suitable for in-depth structural characterization that may not be feasible in other environments. Thus, as an approximation of a native membrane, detergents are able to preserve certain features of membrane proteins such as helix-helix association and native secondary structure. membrane proteins detergents protein folding peptides designed proteins spectroscopy transmembrane segments detergent-protein interactions 0487 0786
57	Detergents as Membrane-mimetic Media for Structural Characterization of Membrane Proteins Tulumello, David 31 August 2012 (has links) Membrane proteins are essential cellular components, responsible for a wide variety of biological functions. In order to better understand such aspects of cell activity, researchers have pursued detailed structural analysis of this class of proteins. Because of the complexities in isolating and studying membrane proteins in their native environment, detergents are often employed as a membrane mimetic media. This thesis examines several features of transmembrane (TM) protein structure and folding in detergents through which we are able to gain insights into membrane protein folding, as well as explore the suitability of detergents as membrane-mimetic environments. We first compare the helix-helix association of a series of model TM sequences in a native bilayer to the corresponding association in a detergent environment. We find that while various classes of helix-helix interaction motifs are preserved in detergents, alterations in detergent solvation may, in turn, lead to altered association affinity. We further explore this phenomenon through investigation of the consequences of the insertion of a strongly polar residue into a TM segment. In these studies we find a correlation between sequence-dependent alterations in detergent solvation and predicted in vivo folding. We also extend such analyses to a variety of detergents and native TM segments, finding that native secondary structure, as it occurs in the context of a full-length protein, is generally well preserved in a variety of detergents. Finally, we assess the determinants of membrane protein folding using two-transmembrane segment constructs, in the process optimizing expression, production and characterization techniques for a diverse range of transmembrane protein sequences. Overall this thesis finds that, detergents are capable of solubilizing membrane proteins in a form suitable for in-depth structural characterization that may not be feasible in other environments. Thus, as an approximation of a native membrane, detergents are able to preserve certain features of membrane proteins such as helix-helix association and native secondary structure. membrane proteins detergents protein folding peptides designed proteins spectroscopy transmembrane segments detergent-protein interactions 0487 0786
58	Biophysical characterization of the energy and TonB-dependence of the ferric enterobactin transport protein FepA Jordan, Lorne Donnell January 1900 (has links) Doctor of Philosophy / Biochemistry and Molecular Biophysics / Phillip E. Klebba / The goal of the research included in this dissertation is to provide a more complete model of the role of TonB, an energy transducing protein that resides in the inner membrane and is an essential component of the iron transport of Escherichia coli under iron-starved conditions. Using fluorescent hybrid proteins, the anisotropy of TonB in the cytoplasmic membrane (CM) of Escherichia coli was determined. With the aim of understanding the bioenergetics of outer membrane (OM) iron transport, the dependence of TonB motion on the electrochemical gradient and the effect of CM proteins ExbB and ExbD on this phenomenon was monitored and analyzed. The native E. coli siderophore, enterobactin chelates Fe⁺³ in the environment and ferric enterobactin (FeEnt) enters the cell by energy- and TonB-dependent uptake through FepA, its OM transporter. The TonB-ExbBD complex in the CM is hypothesized to transfer energy to OM transporters such as FepA. We observed the polarization of GFPTonB hybrid proteins and used metabolic inhibitors (CCCP, azide and dinitrophenol) and chromosomal deletions of exbBD to study these questions. The results showed higher anisotropy (R) values for GFP-TonB in energy-depleted cells, and lower R-values in bacteria lacking ExbBD. Metabolic inhibitors did not change the anisotropy of GFP-TonB in ΔexbBD cells. These findings suggest that TonB undergoes constant, energized motion in the bacterial CM, and that ExbBD mediates its coupling to the electrochemical gradient. By spectroscopic analyses of extrinsic fluorophore labeled site-directed Cys residues in 7 surface loops of Escherichia coli FepA, binding and transport of ferric enterobactin (FeEnt) was characterized. Changes in fluorescence emissions reflected conformational motion of loops that altered the environment of the fluorophore, and we observed these dynamics as quenching phenomena during FeEnt binding and transport in living cells or outer membrane vesicles. Cys residues in each of the 7 surface loops (L2, L3, L4, L5, L7 L8, and L11) behaved individually and characteristically with regard to both fluorophore maleimide reactivity and conformational motion. Fluorescence measurements of FeEnt transport, by either microscopic or spectroscopic methodologies, demonstrated that ligand uptake occurs uniformly throughout the cell envelope, and susceptibility of FeEnt uptake to the proton ionophore m-chlorophenyl hydrazone (CCCP) at concentrations as low as 5 uM. The latter result recapitulates the sensitivity of inner membrane major facilitator transporters to CCCP (Kaback, 1974), providing further evidence of the electrochemical gradient as a driving force for TonB-dependent metal transport. Iron transport Escherichia coli TonB-dependent Fluorescence anisotropy FepA Enterobactin Biochemistry (0487) Biophysics (0786)
59	NC-1059, a channel forming peptide, induces a reversible change in barrier function of epithelial monolayers Somasekharan, Suma January 1900 (has links) Doctor of Philosophy / Department of Biochemistry / Bruce D. Schultz / John M. Tomich / NC-1059 is a synthetic channel-forming peptide that provides for ion transport across, and transiently reduces barrier integrity of, cultured epithelial monolayers derived from canine kidney (MDCK cells; Broughman, J. R. et al; Am J Physiol Cell Physiol 286: C1312-23). In this first study experiments were conducted to determine whether epithelial cells derived from other sources were similarly affected. Human (T84, Calu-3) and non-human (IPEC-J2, PVD9902) epithelial cells derived from intestinal (T84, IPEC-J2), airway (Calu-3), and genitourinary (PVD9902) tissues were grown on permeable supports. Ion transport and barrier function were assessed electrically in a modified Ussing chamber. Basal short circuit current (I[subscript sc]) was typically less than 3 [Mu]A cm[superscript-2]. Apical NC-1059 exposure caused, in all cell types, an increase in I[subscript sc] to >15 [Mu]A cm[superscript-2], indicative of net anion secretion or cation absorption that was followed by an increase in transepithelial conductance (g[subscript te] in mS cm[superscript-2]; T-84, 1.6 to 62; PVD9902, 0.2 to 51; IPEC-J2, 0.3 to 26; Calu-3, 2.2 to 13). NC-1059 induces a concentration dependent change in the I[subscript sc] and g[subscript te] across these epithelia. The results in all cases were consistent with both a transcellular and a paracellular effect of the peptide. NC-1059 enhanced permeation of dextrans ranging from 10 kDa to 70 kDa across all epithelia tested. These results document an effect of NC-1059 on the paracellular route of epithelial barriers. Immunolabeling, confocal microscopy and immunoblotting methods were used in a second study to assess the molecular changes associated with increased paracellular permeability. NC-1059 induced a substantial reorganization of actin within 60 minutes of exposure. Confocal microscopy revealed that the changes in actin organization were accompanied by a pronounced change in the abundance and distribution of tight junction proteins occludin and ZO-1. Immunoblotting results suggest a time and concentration dependent effect on cellular abundance of these tight junction proteins. The effects on g[subscript te] and junctional proteins are transient with > 85% of recovery in 24 hours post exposure and full recovery within 48 hours. The reversible modulation of the epithelial tight junctions has therapeutic potential to increase the efficiency of drug delivery across barrier membranes. Epithelia Paracellular Tight Junctions Conductance Biology, Animal Physiology (0433) Biology, Cell (0379) Biophysics, General (0786)
60	Biophysical characterization of branched amphiphilic peptide capsules and their potential applications in radiotherapy Sukthankar, Pinakin Ramchandra January 1900 (has links) Doctor of Philosophy / Department of Biochemistry and Molecular Biophysics / John M. Tomich / Branched Amphiphilic Peptide Capsules (BAPCs) are peptide nano-spheres comprised of equimolar proportions of two branched peptide sequences bis(FLIVI)-K-KKKK and bis(FLIVIGSII)-K-KKKK that self-assemble in water to form bilayer delimited poly-cationic capsules capable of trapping solutes. We examined the lipid-like properties of this system including assembly, fusion, solute encapsulation, and resizing by membrane extrusion as well as their capability to be maintained at a specific size by storage at 4˚C. These studies along with earlier work from the lab (Gudlur et al. (2012) PLOS ONE 7(9): e45374) demonstrated that the capsules, while sharing many properties with lipid vesicles, were much more robust. We next investigated the stability, size limitations of encapsulation, cellular localization, retention and, bio-distribution of the BAPCs. We demonstrated that the BAPCs are readily taken up by epithelial cells in culture, escape or evade the endocytotic pathway, and accumulate in the peri-nuclear region where they persist without any apparent degradation. The stability and persistence of the capsules suggested they might be useful in delivering radionuclides. The BAPCs encapsulated alpha particle emitting radionuclides without any apparent leakage, were taken up by cells and were retained for extended periods of time. Their potential in this clinical application is being currently pursued. Lastly we studied the temperature dependence of capsule formation by examining the biophysical characteristics of temperature induced conformational changes in BAPCs and examined the structural parameters within the sequences that contribute to their remarkable stability. A region in the nine-residue sequence was identified as the critical element in this process. The ability to prepare stable uniform nano-scale capsules of desired sizes makes BAPCs potentially attractive as delivery vehicles for various solutes/drugs. BAPCs Radiotherapy Alpha particle Nanocapsules Drug delivery Peptide Biochemistry (0487) Biophysics (0786) Biophysics, Medical (0760) Chemistry (0485) Chemistry, Radiation (0754)

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