Thermal degradation of polymer blends containing the poly (hydroxy, ether of bisphenol-A) /

Formosa, Joseph S.

January 1987

Thesis (M.S.)--Rochester Institute of Technology, 1987. / Typescript. Includes bibliographical references (leaves 73-74).

Polymers Polymers Phenoxy groups.

Effect of phenoxy acids and their derivatives on the ionic permeability of bilayer lipid membranes

Illangasekare, Malkanthi Paulis

01 January 1979

It has been found that the herbicide 2,4-D has the ability to increase the rate of transport of positive ions of several kinds and inhibit the transport of negatively charged tetraphenylborate ions in lipid bilayer membranes. Only the neutral molecules of 2,4-D are transport active. The ionized 2,4-D molecules do not modify the transport of ions, and do not by themselves permeate through lipid membranes. The results suggest that the enhancement of transport of positively charged ions is dominated by the increase of the ion translocation rate constant. It has been shown that membrane transport of negatively charged tetraphenylborate ions is suppressed by 2,4-D. The effect is dominated by the suppression of translocation of these ions across membrane interior, rather than by the decrease of their adsorption at the membrane surface. It has been shown that the enhancement of nonactin-mediated transport of potassium ions by 2,4-D can be accounted for by a simple carrier model. From the changes of kinetic parameters of nonactin-K('+) transport, membrane conductance due to positively charged tetraphenylarsonium ions and also from the changes of membrane conductance and relaxation time constant due to transport of negatively charged tetraphenylborate ions, the changes of the electric potential of the membrane interior have been estimated. The potential of the membrane interior becomes more negative in the presence of 2,4-D and its change is proportional to the aqueous concentration of 2,4-D. The effect of 2,4-D on ion transport was explained by the hypothesis that a layer of 2,4-D molecules is absorbed within the membrane/water interfacial region, and that the 2,4-D molecules are oriented in such a way that their dipole moment is directed toward the aqueous medium. The results suggest that this layer is located in the hydrocarbon side of the interface. The hypothesis has been confirmed by the measurements of changes of electric potential difference across air/water and air/lipid monolayer/water interfaces. It has been found that the electric potential of the nonpolar side of the interface decreases in the presence of neutral molecules of 2,4-D, which is in agreement with the conclusions drawn from the results of membrane experiments. The effect of the other auxin-type phenoxy herbicides, 2,4,5-T and 2,4-DB on lipid bilayer membranes has been found to be similar to that of 2,4-D. In contrast, the phenoxy acid 2,4,6-T, has very little or no herbicidal activity, and at the same time has small effect on ion transport in membranes. Biologically active 2,4-D derivatives, amino acid conjugates of 2,4-D (isoleucine, leucine and valine conjugates) have been found to be also transport active in a manner similar to 2,4-D. Similar conclusions have been drawn from experiments with natural auxin indole acetic acid. The results obtained in this work suggest the existence of correlation between the biological activity of herbicides acting as plant growth regulators and their ability to enhance transport of positively charged ions across lipid membranes. This work provides insight into the physical origin of such activity.

Biophysics

Bilayer lipid membranes

Ion-permeable membranes

Phenoxy groups

Properties of C-linked C8-phenoxyl guanine DNA adducts

Millen, Andrea

January 2011

DNA damage is important to understand since it has the potential to lead to disease if unrepaired. In particular, bulky C8 guanine adducts (addition products) are known to induce a variety of mutations due to their conformational flexibility. C-linked C8-phenoxyl-deoxyguanosine adducts (PhOH-dG) have been poorly understood despite their potential for genotoxicity. This thesis systematically develops a computational model to predict the conformational and base-pairing preferences of PhOH-dG by gradually increasing the size of the system. The structure of PhOH-dG in DNA is determined, where the bulky C8 group induces a syn conformation of the base similar to other C8-adducts. A stabilized guanine mismatch is identified for the syn adducts, which implies that the primary mechanism of genotoxicity may be base-substitution mutations resulting in G→C transversions. This thesis has contributed to a growing body of literature dedicated to understanding the role of conformational heterogeneity in the mutagenicity of bulky C8-adducts. / xix, 192 leaves : ill. (some col.) ; 29 cm

DNA damage -- Research

DNA adducts -- Research

DNA adducts -- Computer simulation

Genetic toxicology -- Research

Mutagenesis

Phenoxy groups

Radicals (Chemistry)