Alzheimer's disease is characterized pathologically by abnormal depositions of ? amyloid proteins in the brain, called senile plaques. Unfortunately, the pathophysiological role of the ?-amyloid peptides in causing Alzheimer's disease and how senile plaques affect the neuronal membrane is still unknown. Although many findings strongly indicate that the pathophysiological effects of amyloid plaques may partially be caused by direct interactions between membrane lipids and ?-amyloid peptides, the molecular basis of the interaction is still not well understood. According to one hypothesis, the ?-amyloid peptides interact electrostatically with the neuronal membrane, while according to another, the interaction is hydrophobic such that the peptide penetrates the membrane and disrupts its functionality. Furthermore, a great number of studies indicate that cholesterol or cholesterol metabolism may be important in the pathophysiology of Alzheimer's disease. Therefore, it would be very important to elucidate how depletion or enrichment of cholesterol relates to Alzheimer's disease. The main goal in this project is to elucidate the interaction of the ?-amyloid peptide (25- 35) and phospholipid model membranes with and without cholesterol by using new electron paramagnetic resonance (EPR) methods developed in our laboratory. The working hypothesis is that the hydrophobic part of ?AP(25-25) penetrates into the phospholipid bilayer and thus changes the fluidity of the bilayer, making the membrane more rigid, while at the same time due to the insertion of the peptide the permeability of the membrane increases to allow a deeper penetration of water and cations into the bilayer. These two interactions disrupt the phospholipid bilayer and can account for one of the possible mechanisms for ?AP(25-25) neurotoxicity. Cholesterol added to the phospholipid bilayer should reduce the insertion of ?AP(25-25) into the bilayer, and thus preserve bilayer integrity from the disrupting effect of the ?-amyloid peptide, thereby reducing the neurotoxicity of the peptide. To test the hypothesis, we propose conducting a wide range of electron paramagnetic resonance experiments on phospholipid vesicles, peptide-phospholipid vesicles, cholesterol-phospholipid vesicles and peptide-cholesterol-phospholipid vesicles. These experiments are designed to give a complete knowledge of the changes in membrane fluidity and permeability across the phospholipid bilayer, so that the location of the peptide in the phospholipid bilayer and the structural changes of the aggregate as a whole can be determined. This information may provide new insight into how the ?-amyloid peptide affects the neurodegenerative process associated with Alzheimer's disease.

Public Health Relevance

Knowledge of the molecular interaction of the ?-amyloid peptides (?AP) and phospholipid membranes may provide new insights in the neurodegenerative process associated with Alzheimer's disease. A better understanding of the interaction between cholesterol and ?AP in the phospholipid bilayer may contribute to the improvement of already existing treatments, such as cholesterol-reducing drugs. In addition, this understanding might lead to the development of new therapeutic approaches in treating Alzheimer's disease.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Continuance Award (SC3)
Project #
5SC3GM099635-02
Application #
8448684
Study Section
Special Emphasis Panel (ZGM1-MBRS-1 (SC))
Program Officer
Okita, Richard T
Project Start
2012-04-01
Project End
2016-03-31
Budget Start
2013-04-01
Budget End
2014-03-31
Support Year
2
Fiscal Year
2013
Total Cost
$104,944
Indirect Cost
$32,569
Name
California State University Northridge
Department
Physics
Type
Schools of Arts and Sciences
DUNS #
055752331
City
Northridge
State
CA
Country
United States
Zip Code
91330
Singh, Jasmeet; Peric, Miroslav (2018) Interaction of the ? amyloid - A?(25-35) - peptide with zwitterionic and negatively charged vesicles with and without cholesterol. Chem Phys Lipids 216:39-47
Bales, Barney L; Peric, Miroslav (2017) EPR Line Shifts and Line Shape Changes Due to Spin Exchange Between Nitroxide Free Radicals in Liquids 10. Spin-Exchange Frequencies of the Order of the Nitrogen Hyperfine Interaction: A Hypothesis. Appl Magn Reson 48:175-200
Merunka, Dalibor; Peric, Miroslav (2017) Continuous Diffusion Model for Concentration Dependence of Nitroxide EPR Parameters in Normal and Supercooled Water. J Phys Chem B 121:5259-5272
Merunka, Dalibor; Peric, Mirna; Peric, Miroslav (2015) Study of nanostructural organization of ionic liquids by electron paramagnetic resonance spectroscopy. J Phys Chem B 119:3185-93
Peric, Ida; Merunka, Dalibor; Bales, Barney L et al. (2014) Hydrodynamic and nonhydrodynamic contributions to the bimolecular collision rates of solute molecules in supercooled bulk water. J Phys Chem B 118:7128-35
Bales, Barney L; Meyer, Michelle; Peric, Miroslav (2014) EPR line shifts and line shape changes due to Heisenberg spin exchange and dipole-dipole interactions of nitroxide free radicals in liquids: 9. An alternative method to separate the effects of the two interactions employing ¹?N and ¹?N. J Phys Chem A 118:6154-62
Peric, Ida; Merunka, Dalibor; Bales, Barney L et al. (2013) Rotation of Four Small Nitroxide Probes in Supercooled Bulk Water. J Phys Chem Lett 4:508-513
Vandenberg, Andrew D; Bales, Barney L; Salikhov, K M et al. (2012) Bimolecular encounters and re-encounters (cage effect) of a spin-labeled analogue of cholestane in a series of n-alkanes: effect of anisotropic exchange integral. J Phys Chem A 116:12460-9