Studies on small molecule-protein interactions with a note on the use of tracers in transport systems

Arvidsson, Erik Olof.

January 1900

Thesis (doctoral)--University of Lund.

Protein Binding.

Studies on small molecule-protein interactions with a note on the use of tracers in transport systems

Arvidsson, Erik Olof.

January 1900

Thesis (doctoral)--University of Lund.

Protein Binding.

Localization and Distribution of Binging Sites for Atrial Natriuretic Factor in the Rat: A Light and Electron Microscope Radioautographic Study

Bianchi Filho, Cesario

January 1988

Note:

Binding sites

Electrochemical detection of interactions between DNA and various ligands

Muresan, Alina

04 December 2007

Antibodies specific for DNA, with varying degrees of sequence specificity, are common in many autoimmune diseases including systemic lupus erythematosus. The presence of anti-DNA antibodies is a useful determinant in arriving at a prognosis in these conditions. Given the prevalence of these diseases in both the developing and developed world and the difficulty that often accompanies diagnosis of autoimmune diseases, it is desirable to have sensitive, rapid, and inexpensive diagnostic tools for these diseases. Because of the great sensitivity of electrochemical techniques and their potential utility in characterizing interactions between macromolecules, electrochemistry has great potential as a diagnostic tool for any disease involving antibodies. Anti-DNA antibodies are present in many autoimmune diseases, notably systemic lupus erythematosus. Since DNA is a stable and well-characterized antigen, an electrochemical-based assay is particularly useful for diagnosis of these diseases. <p>The impedance of a gold surface was measured in the presence and absence of single- and double-stranded DNA monolayers. The DNA monolayer was diluted with butanethiol in order to provide a surface with more accessible binding sites than an undiluted monolayer. The change in impedance of the DNA monolayer following exposure to various small molecules and macromolecules was assessed. The molecules used included polyamines that induce conformational changes in DNA, proteins which bind DNA specifically, proteins which bind DNA non-specifically, and proteins which do not bind DNA. The presence of a DNA monolayer, whether single- or double-stranded, increased the impedance of the gold surface and dilution of the monolayers by butanethiol decreased the impedance, as expected. When exposed to polyamines, the impedance of the DNA monolayer decreased further. This could be due to lowered charge repulsion, to DNA condensation, or to a combination of both. When methylated bovine serum albumin was exposed to the monolayer, there was an increase in impedance. Conversely, when bovine serum albumin was exposed to the monolayer, the impedance was only increased at very high concentrations of protein. The increase following exposure to high concentrations of bovine serum albumin was likely due to deposition of protein on to the monolayer. The specificity of these interactions was illustrated by experiments with the antibody Hed 10, which binds single-stranded but not double-stranded DNA. Exposure to Hed 10 only caused a significant change in impedance when exposed to monolayers of single-stranded DNA.<p>The decreased impedance of the DNA monolayer caused by the presence of polyamines is consistent with the known structural perturbations induced by these molecules as measured with other methods. Similarly, the increase in impedance caused by the presence of proteins which bind DNA is consistent with increased steric interference by the protein-DNA complex. The failure of proteins which do not bind DNA to affect the impedance of the monolayer indicated that the effects in the experiments with DNA-binding proteins were due to protein binding and not other factors. The specificity of the assay as demonstrated by the results of the experiments with Hed 10 suggest that impedance-based measurements may provide the basis for a reliable, sensitive, and inexpensive assay for detecting the presence of anti-DNA antibodies in the serum of autoimmune disease patients.

DNA-binding drugs

DNA-binding proteins

electrochemistry

Electrochemical detection of interactions between DNA and various ligands

Muresan, Alina

04 December 2007

Antibodies specific for DNA, with varying degrees of sequence specificity, are common in many autoimmune diseases including systemic lupus erythematosus. The presence of anti-DNA antibodies is a useful determinant in arriving at a prognosis in these conditions. Given the prevalence of these diseases in both the developing and developed world and the difficulty that often accompanies diagnosis of autoimmune diseases, it is desirable to have sensitive, rapid, and inexpensive diagnostic tools for these diseases. Because of the great sensitivity of electrochemical techniques and their potential utility in characterizing interactions between macromolecules, electrochemistry has great potential as a diagnostic tool for any disease involving antibodies. Anti-DNA antibodies are present in many autoimmune diseases, notably systemic lupus erythematosus. Since DNA is a stable and well-characterized antigen, an electrochemical-based assay is particularly useful for diagnosis of these diseases. <p>The impedance of a gold surface was measured in the presence and absence of single- and double-stranded DNA monolayers. The DNA monolayer was diluted with butanethiol in order to provide a surface with more accessible binding sites than an undiluted monolayer. The change in impedance of the DNA monolayer following exposure to various small molecules and macromolecules was assessed. The molecules used included polyamines that induce conformational changes in DNA, proteins which bind DNA specifically, proteins which bind DNA non-specifically, and proteins which do not bind DNA. The presence of a DNA monolayer, whether single- or double-stranded, increased the impedance of the gold surface and dilution of the monolayers by butanethiol decreased the impedance, as expected. When exposed to polyamines, the impedance of the DNA monolayer decreased further. This could be due to lowered charge repulsion, to DNA condensation, or to a combination of both. When methylated bovine serum albumin was exposed to the monolayer, there was an increase in impedance. Conversely, when bovine serum albumin was exposed to the monolayer, the impedance was only increased at very high concentrations of protein. The increase following exposure to high concentrations of bovine serum albumin was likely due to deposition of protein on to the monolayer. The specificity of these interactions was illustrated by experiments with the antibody Hed 10, which binds single-stranded but not double-stranded DNA. Exposure to Hed 10 only caused a significant change in impedance when exposed to monolayers of single-stranded DNA.<p>The decreased impedance of the DNA monolayer caused by the presence of polyamines is consistent with the known structural perturbations induced by these molecules as measured with other methods. Similarly, the increase in impedance caused by the presence of proteins which bind DNA is consistent with increased steric interference by the protein-DNA complex. The failure of proteins which do not bind DNA to affect the impedance of the monolayer indicated that the effects in the experiments with DNA-binding proteins were due to protein binding and not other factors. The specificity of the assay as demonstrated by the results of the experiments with Hed 10 suggest that impedance-based measurements may provide the basis for a reliable, sensitive, and inexpensive assay for detecting the presence of anti-DNA antibodies in the serum of autoimmune disease patients.

DNA-binding drugs

DNA-binding proteins

electrochemistry

Diversity in competitive ligand-receptor interactions : electrophysiological studies of ligand-receptor interactions at native and recombinant GABAA receptors /

Vestergaard, Henrik Tang.

January 2003

Ph D.

Computational methods for the measurement of protein-DNA interactions

James, Daniel Peter

January 2018

It is of interest to know where in the genome DNA binding proteins act in order to effect their gene regulatory function. For many sequence specific DNA binding proteins we plan to predict the location of their action by having a model of their affinity to short DNA sequences. Existing and new models of protein sequence specificty are investigated and their ability to predict genomic locations is evaluated. Public data from a micro-fluidic experiment is used to fit a matrix model of binding specificity for a single transcription factor. Physical association and disassociation constants from the experiment enable a biophysical interpretation of the data to be made in this case. The matrix model is shown to provide a better fit to the experimental data than a model initially published with the data. Public data from 172 protein binding micro-array experiments is used to fit a new type of model to 82 unique proteins. Each experiment provides measurements of the binding specificity of an individual protein to approximately 40000 DNA probes. Statistical, `DNA word', models are assessed for their ability to predict held back data and perform very well in many cases. Where available, ChIP-seq data from the ENCODE project is used to assess the ability of a selection of the DNA word models to predict ChIP-seq peaks and how they compare to matrix models in doing so. This $\textit{in vitro}$ data is the closest proxy to the true sites of the proteins' regulatory action that we have.

Studies on serum albumin binding of various lysolecithins

Barlow, W. Mack

January 2011

Digitized by Kansas Correctional Industries

Lipoproteins

Protein binding

Sequence-selective binding of quinoxaline antibiotics to DNA and nucleosome core particles

Low, C. M. L.

January 1985

No description available.

615.1

Antibiotic-DNA binding

Immunochemical studies of mammalian beta-galactoside ?-binding lectins

Carding, S. R.

January 1985

No description available.

572

Carbohydrate-binding proteins