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Combinatorial Microscopy of Molecular Interactions at Membrane InterfacesOreopoulos, John 13 June 2011 (has links)
Biological membranes are heterogeneous two-dimensional fluids composed of lipids, sterols and proteins that act as complex gateways and define the cell boundary. The functions of these interfaces are diverse and specific to individual organisms, cell types, and tissues. Membranes must take up nutrients and small molecules, release waste products, bind ligands, transmit signals, convert energy, sense the environment, maintain cell adhesion, control cell migration, and much more while forming a tight barrier around the cell. The molecular mechanisms and structural details responsible for this diverse set of functions of biological membranes are still poorly understood, however. Developing new tools capable of probing and determining the local molecular organization, structure, and dynamics of membranes and their components is critical for furthering our knowledge about these important cellular processes that are often linked to health and diseases.
Combinatorial microscopy takes advantage of the rich properties of light (intensity, wavelength, polarization, etc.) to create new forms of imaging that quantify the motions, orientations, and binding kinetics of the sample’s biomolecular constituents. These new optical imaging modalities can also be further combined with other types of microscopy to produce spatially correlated micrographs that provide complementary pieces of information about the sample under investigation that would otherwise remain hidden from the observer if the two imaging techniques were applied independently. The first part of this thesis provides a detailed account of the construction of a specialized hybrid microscopy platform that combines polarized total internal reflection fluorescence microscopy (pTIRFM) with atomic force microscopy (AFM) for the purpose of studying fundamental sterol-lipid and antimicrobial peptide-lipid interactions in model membranes. The second half describes a combined pTIRFM and Förster resonance energy transfer (FRET) imaging method to elucidate the oligomeric state and spatial distribution of carcinoembryonic-antigen-related cell-adhesion molecules (CEACAMs) in the membranes of living cells.
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Biophysical Characterization of Cell-Penetrating Peptides for Cargo Delivery or Lipid-SensingVinay K. Menon (15295864) 13 June 2023 (has links)
<p>Peptides, specifically cell-penetrating peptides (CPP), have become wonderful research tools due to their enhanced stability, solubility, and ease of synthesis. They have been used for a wide range of biomedical applications, from insecticides to biosensors and drug-delivery scaffolds. The work presented in this dissertation characterizes the biophysical properties of two different CPPs. The first is the cationic amphiphilic polyproline helix (CAPH) peptide, P14LRR. In addition to cell penetration, this CPP has demonstrated broad spectrum antibacterial properties. Fluorescence polarization (FP) and SEC-MALS were conducted to understand the dissociation constant (KD) and oligomerization effects of P14LRR with respect to its putative molecular target in Staphylococcus aureus (S. aureus). A biotinylated derivative of this peptide was also used as a drug-delivery scaffold to transport fluorescently conjugated streptavidin into mammalian cells. A second CPP, DAN13, was also developed as a biosensor for phosphoinositide lipids, specifically PI(4,5)P2. This was effected through careful calibration using stacked supported lipid bilayers (SSLB) in combination with total internal reflection fluorescence (TIRF) microscopy. This was then used to determine the absolute densities and spatial distribution of PIP2 in live KRas mutant cells.</p>
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