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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

Binding of Self-assembling Peptides to Oligodeoxynucleotides

Wang, Mei January 2007 (has links)
This thesis is an experimental investigation on the binding of self-assembling peptides to oligodeoxynucleotides (ODNs) and the characterization of the resulting peptide-ODN complexes/aggregates, the first key step in the development of a peptide-based gene delivery system. Effects of pH, charge distribution along the peptide backbone, and oligonucleotide sequences on the peptide-ODN binding were investigated by a series of physicochemical methods. UV-Vis absorption and fluorescence anisotropy experiments demonstrate that aggregates are formed after mixing the peptide and ODN in aqueous solution. The aggregates in solution can be centrifuged out. Based on this property, the fraction of ODNs incorporated in the peptide-ODN aggregates can be obtained by comparing the UV-Vis absorption of the solution before and after centrifugation. Binding isotherms are generated by a binding density function analysis of the UV absorbance results. The binding parameters are extracted from the analysis of the binding isotherms based on the McGhee and von Hippel model. Equilibrium binding parameter studies show that the binding of two self-assembling peptides, EAK16-II and EAK 16-IV, to model single and double-stranded ODNs at pH 4 is stronger than at pH 7, and that no binding occurs at pH 11. These results demonstrate that electrostatic interactions play an important role in the EAK-ODN binding because EAKs are more positively charged at low pH. EAKs bind more strongly to dG16 than to the other ODN sequences dC16 and dGC16. This demonstrates that the hydrogen bond might be involved because they promote the binding of the lysine residues of the peptide to dG16 to a greater extent than to dC16. The charge distribution along the peptides is found to have an effect on the binding. EAK16-IV, whose positively charged residues are clustered at one end of the peptide, binds to the ODNs more strongly than EAK16-II, whose positively charged residues are distributed throughout the peptide chain, at the same pH. The binding process of EAKs to the ODNs was investigated by fluorescence anisotropy and static light scattering experiments. The results show that individual EAK and ODN molecules complex first, followed by the aggregation of these complexes into large aggregates. The nature of the resulting peptide-ODN complexes/aggregates is examined by UV-Vis absorption, fluorescence anisotropy, and PAGE experiments. The results demonstrate that free EAK, free ODNs, and small EAK-ODN complexes, which can not be centrifuged out, exist in the supernatant, and that large aggregates are collected in the pellets after centrifugation of the solution. The size of the resulting EAK-ODN complexes/aggregates measured by AFM and DLS is around a few hundreds of nanometers at low EAK concentrations. The accessibility of the ODNs to the quencher in the solution is reduced by 40 % and 60 % after binding to EAK16-II and EAK16-IV, respectively, as determined by fluorescence quenching experiments on EAK-ODN mixture solutions. An ODN protection from Exonuclease 1 degradation is provided by the EAK16-II or EAK16-IV matrix when they are mixed with the ODNs at pH 4. However, the ODNs are protected to a much lower degree when the EAK-ODN aggregates are prepared at pH 7. The EAK-ODN aggregates prepared at pH 7 are found to dissociate more easily than those prepared at pH 4 when they are incubated with exonuclease I solution at pH 9.5. These results suggest that the ODN protection afforded by the EAK-ODN aggregates is correlated with their structural stability after being incubated with the nuclease solution. The stability of the EAK-ODN aggregates after dilution is determined by UV-Vis absorption. No detectable dissociation of the aggregates is observed over 20 hrs after a 5- and 10-fold dilution of the solution in the same buffer used for their preparation. The EAK-ODN aggregates remain stable after the solutions are centrifuged, and re-dissolved in fresh buffer solutions. The ability of an EAK matix to protect ODNs from nuclease degradation together with its biocompatibility and low-toxicity suggests that EAK self-assembling peptides could be used as carriers for gene delivery.
2

Binding of Self-assembling Peptides to Oligodeoxynucleotides

Wang, Mei January 2007 (has links)
This thesis is an experimental investigation on the binding of self-assembling peptides to oligodeoxynucleotides (ODNs) and the characterization of the resulting peptide-ODN complexes/aggregates, the first key step in the development of a peptide-based gene delivery system. Effects of pH, charge distribution along the peptide backbone, and oligonucleotide sequences on the peptide-ODN binding were investigated by a series of physicochemical methods. UV-Vis absorption and fluorescence anisotropy experiments demonstrate that aggregates are formed after mixing the peptide and ODN in aqueous solution. The aggregates in solution can be centrifuged out. Based on this property, the fraction of ODNs incorporated in the peptide-ODN aggregates can be obtained by comparing the UV-Vis absorption of the solution before and after centrifugation. Binding isotherms are generated by a binding density function analysis of the UV absorbance results. The binding parameters are extracted from the analysis of the binding isotherms based on the McGhee and von Hippel model. Equilibrium binding parameter studies show that the binding of two self-assembling peptides, EAK16-II and EAK 16-IV, to model single and double-stranded ODNs at pH 4 is stronger than at pH 7, and that no binding occurs at pH 11. These results demonstrate that electrostatic interactions play an important role in the EAK-ODN binding because EAKs are more positively charged at low pH. EAKs bind more strongly to dG16 than to the other ODN sequences dC16 and dGC16. This demonstrates that the hydrogen bond might be involved because they promote the binding of the lysine residues of the peptide to dG16 to a greater extent than to dC16. The charge distribution along the peptides is found to have an effect on the binding. EAK16-IV, whose positively charged residues are clustered at one end of the peptide, binds to the ODNs more strongly than EAK16-II, whose positively charged residues are distributed throughout the peptide chain, at the same pH. The binding process of EAKs to the ODNs was investigated by fluorescence anisotropy and static light scattering experiments. The results show that individual EAK and ODN molecules complex first, followed by the aggregation of these complexes into large aggregates. The nature of the resulting peptide-ODN complexes/aggregates is examined by UV-Vis absorption, fluorescence anisotropy, and PAGE experiments. The results demonstrate that free EAK, free ODNs, and small EAK-ODN complexes, which can not be centrifuged out, exist in the supernatant, and that large aggregates are collected in the pellets after centrifugation of the solution. The size of the resulting EAK-ODN complexes/aggregates measured by AFM and DLS is around a few hundreds of nanometers at low EAK concentrations. The accessibility of the ODNs to the quencher in the solution is reduced by 40 % and 60 % after binding to EAK16-II and EAK16-IV, respectively, as determined by fluorescence quenching experiments on EAK-ODN mixture solutions. An ODN protection from Exonuclease 1 degradation is provided by the EAK16-II or EAK16-IV matrix when they are mixed with the ODNs at pH 4. However, the ODNs are protected to a much lower degree when the EAK-ODN aggregates are prepared at pH 7. The EAK-ODN aggregates prepared at pH 7 are found to dissociate more easily than those prepared at pH 4 when they are incubated with exonuclease I solution at pH 9.5. These results suggest that the ODN protection afforded by the EAK-ODN aggregates is correlated with their structural stability after being incubated with the nuclease solution. The stability of the EAK-ODN aggregates after dilution is determined by UV-Vis absorption. No detectable dissociation of the aggregates is observed over 20 hrs after a 5- and 10-fold dilution of the solution in the same buffer used for their preparation. The EAK-ODN aggregates remain stable after the solutions are centrifuged, and re-dissolved in fresh buffer solutions. The ability of an EAK matix to protect ODNs from nuclease degradation together with its biocompatibility and low-toxicity suggests that EAK self-assembling peptides could be used as carriers for gene delivery.
3

From the inside out : determining sequence conservation within the context of relative solvent accessibility

Scherrer, Michael Paul 17 October 2013 (has links)
Evolutionary rates vary vastly across intraspecific genes and the determinants of these rates is of central concern to the field of comparative genomics. Tradition has held that preservation of protein function conserved the sequence, however mounting evidence implicates the biophysical properties of proteins themselves as the elements that constrain sequence evolution. Of these properties, the exposure of a residue to solvent is the most prevalent determinant of its evolutionary rate due to pressures to maintain proper synthesis and folding of the structure. In this work, we have developed a model that considers the microenvironment of a residue in the estimation of its evolutionary rate. By working within the structural context of a protein's residues, we show that our model is better able to capture the overall evolutionary trends affecting conservation of both the coding sequences and the protein structures from a genomic level down to individual genes. / text
4

Enhanced prediction of Phosphorylation and Disorder in Proteins

Swaminathan, Karthikeyan January 2009 (has links)
No description available.
5

Net Evolutionary Loss of Residue Polarity in Drosophilid Protein Cores Indicates Ongoing Optimization of Amino Acid Composition

Yampolsky, Lev Y., Wolf, Yuri I., Bouzinier, Michael A. 01 October 2017 (has links)
Amino acid frequencies in proteins may not be at equilibrium. We consider two possible explanations for the nonzero net residue fluxes in drosophilid proteins. First, protein interiors may have a suboptimal residue composition and be under a selective pressure favoring stability, that is, leading to the loss of polar (and the gain of large) amino acids. One would then expect stronger net fluxes on the protein interior than at the exposed sites. Alternatively, ifmost of the polarity loss occurs at the exposed sites and the selective constraint on amino acid composition at such sites decreases over time, net loss of polarity may be neutral and caused by disproportionally high occurrence of polar residues at exposed, least constrained sites.We estimated net evolutionary fluxes of residue polarity and volume at sites with different solvent accessibility in conserved protein families from 12 species of Drosophila. Net loss of polarity, miniscule in magnitude, but consistent across all lineages, occurred at all sites except the most exposed ones, where net flux of polaritywas close to zero or, in membrane proteins, even positive. At the intermediate solvent accessibility the net fluxes of polarity and volumewere similar to neutral predictions, whereas much of the polarity loss not attributable to neutral expectations occurred at the buried sites. These observations are consistent with the hypothesis that residue composition in many proteins is structurally suboptimal and continues to evolve toward lower polarity in the protein interior, in particular in proteins with intracellular localization. The magnitude of polarity and volume changes was independent from the protein's evolutionary age, indicating that the approach to equilibrium has been slow or that no such single equilibrium exists.

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