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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Biophysical studies of anhydrous peptide structure

McLean, Janel Renee 15 May 2009 (has links)
Defining the intrinsic properties of amino acids which dictate the formation of helices, the most common protein secondary structure element, is an essential part of understanding protein folding. Pauling and co-workers initially predicted helical peptide folding motifs in the absence of solvent, suggesting that in vacuo studies may potentially discern the role of solvation in protein structure. Ion mobility-mass spectrometry (IMMS) combines a gas-phase ion separation based on collision cross-section (apparent surface area) with time-of-flight MS. The result is a correlation of collision cross-section with mass-to-charge, allowing detection of multiple conformations of the same ion. Most gas-phase peptide ions assume a compact, globular state that minimizes exposure to the low dielectric environment and maximizes intramolecular charge solvation. Conversely, a small number of peptides adopt a more extended (β-sheet or α-helix) conformation and exhibit a larger than predicted collision cross-section. Collision cross-sections measured using IM-MS are correlated with theoretical models generated using simulated annealing and allow for assignment of the overall ion structural motif (e.g. helix vs. chargesolvated globule). Here, two series of model peptides having known solution-phase helical propensities, namely Ac-(AAKAA)nY-NH2 (n = 3, 4, 5, 6 and 7) and Ac-Y(AEAAKA)nF-NH2 (n = 2, 3, 4, and 5), are investigated using IM-MS. Both protonated ([M + H]+) and metalcoordinated ([M + X]+ where X = Li, Na, K, Rb or Cs) species were analyzed to better understand the interplay of forces involved in gas-phase helical structure and stability. The data are analyzed using computational methods to examine the influence of peptide length, primary sequence, and number of basic (Lys, K) and acidic (Glu, E) residues on anhydrous ion structure.
2

Membrane Protein Folding: Modulating the Interactions between Transmembrane Alpha-helices

Ng, Derek 13 January 2014 (has links)
The fundamental process by which an alpha-helical membrane protein attains its ultimate structure has previously been depicted as two energetically distinct stages where (1) the transmembrane (TM) segments are first threaded into the membrane bilayer as stable alpha-helices; and then (2) laterally interact to form the correct tertiary and/or quaternary structures. Central to the second stage of this model is the presence of amino acid sequence motifs in the TM segments that provide interaction-compatible surfaces through which the TM alpha-helices interact. Although these ideas have proven to be pivotal to the progress of the membrane protein folding field, a growing number of examples indicates that a variety of additional factors work together to dictate the ultimate interaction fate of TM embedded segments. In this context, we expand on these factors and explore other properties that can modulate the association of TM alpha-helices. A peptide model of myelin proteolipid protein (PLP) TM4 is capable of TM helix-helix interactions in SDS and biological membranes. Increasing the side chain volumes of two disease relevant residues (Ala242 and A248) reduces peptide self-association, indicating that these sites mediate TM helix packing through van der Waals interactions. Examination of the PLP TM2 alpha-helix shows that it is also capable of self-association and that its dimeric state depends on the presence or absence of residues at its C-terminus. Specifically, this sensitivity was attributed to changes in local hydrophobicity; a decrease in hydrophobicity likely reduces detergent-peptide interactions, which disrupts peptide alpha-helicity and the effectiveness of a nearby interaction compatible surface. We take advantage of this finding to determine the feasibility of coupling helix-helix interactions to an external factor such as pH. Our results indicate that pH can indeed modulate the dimerization state of the TM2 peptide and does so through the change in protonation state of Glu88. Increasing our knowledge of the variables contributing to TM helix-helix interactions provides valuable insights into membrane protein folding and how mutations can compromise this process. This knowledge will allow us to expand our arsenal of approaches to counter membrane protein misassembly--and ultimately human disease.
3

Membrane Protein Folding: Modulating the Interactions between Transmembrane Alpha-helices

Ng, Derek 13 January 2014 (has links)
The fundamental process by which an alpha-helical membrane protein attains its ultimate structure has previously been depicted as two energetically distinct stages where (1) the transmembrane (TM) segments are first threaded into the membrane bilayer as stable alpha-helices; and then (2) laterally interact to form the correct tertiary and/or quaternary structures. Central to the second stage of this model is the presence of amino acid sequence motifs in the TM segments that provide interaction-compatible surfaces through which the TM alpha-helices interact. Although these ideas have proven to be pivotal to the progress of the membrane protein folding field, a growing number of examples indicates that a variety of additional factors work together to dictate the ultimate interaction fate of TM embedded segments. In this context, we expand on these factors and explore other properties that can modulate the association of TM alpha-helices. A peptide model of myelin proteolipid protein (PLP) TM4 is capable of TM helix-helix interactions in SDS and biological membranes. Increasing the side chain volumes of two disease relevant residues (Ala242 and A248) reduces peptide self-association, indicating that these sites mediate TM helix packing through van der Waals interactions. Examination of the PLP TM2 alpha-helix shows that it is also capable of self-association and that its dimeric state depends on the presence or absence of residues at its C-terminus. Specifically, this sensitivity was attributed to changes in local hydrophobicity; a decrease in hydrophobicity likely reduces detergent-peptide interactions, which disrupts peptide alpha-helicity and the effectiveness of a nearby interaction compatible surface. We take advantage of this finding to determine the feasibility of coupling helix-helix interactions to an external factor such as pH. Our results indicate that pH can indeed modulate the dimerization state of the TM2 peptide and does so through the change in protonation state of Glu88. Increasing our knowledge of the variables contributing to TM helix-helix interactions provides valuable insights into membrane protein folding and how mutations can compromise this process. This knowledge will allow us to expand our arsenal of approaches to counter membrane protein misassembly--and ultimately human disease.

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