The Effect of Alcohol on Lipid Membrane-Membrane Fusion and SNARE Proteins

Coffman, Robert E.

19 January 2023

Currently the treatment of alcohol use disorder is very difficult and often requires the combination of therapy and medications, with many who undertake treatment experiencing relapse over time. There is also no treatment in use to prevent the development of alcohol use disorder. It is the aim of this work to provide information that may be useful for the development of a preventative treatment for developing alcohol use disorder by elucidating more of the acute effects of alcohol use. It is known that these effects originate in the brain. Within the brain are circuits made up of neurons that communicate with each other through chemical synapses. These chemical synapses involve the release of neurotransmitters from one neuron that are detected by another neuron, which initiates its own response. It is known that ethanol can change how much neurotransmitter is released from a neuron, depending on the specific neuron tested, and many researchers have implicated the "release machinery" as a target. It is also known that alcohol can affect lipid membrane properties that are important for the fusion of the vesicle membrane, encapsulating the neurotransmitter, with the cell membrane for release of the neurotransmitter outside of the neuron. It is not known if alcohol directly affects the SNARE proteins ("release machinery") or the lipid membranes to initiate the change in neurotransmitter release previously observed. Within this work you will find a discussion of the steps of neurotransmitter release and the known effects of anesthetics on components of this process, as an introduction to the topic (Chapters 1 and 2). In Chapters 3-5 you will find studies that successively dive deeper and deeper into the effects of alcohol on the SNARE proteins and lipid membranes. We show that ethanol is effective at a dose of 0.4% v/v or 64 mM at increasing fusion probability in a model of neurotransmitter release that uses the 3 SNARE proteins to drive fusion of a vesicle with a supported membrane. We also show that alcohol has little direct effect on the SNARE proteins themselves. In addition, we provide evidence that alcohol alters fusion oppositely, depending on which membrane leaflet it has most direct access to. In Chapter 5 we show that alcohol increases the probability of lipid tail protrusion in silico. Previously it has been shown that protrusion of one fatty acid tail of one lipid can initiate fusion of that membrane with an apposing membrane. These data provide further insight into the effects of alcohol on a neuron and we would argue are valuable to research pursuing treatment and prevention of alcohol use disorder.

SNARE protein

molecular dynamics (MD) simulation

circular dichroism

neurotransmitter release

exocytosis

adaptive biasing force

Life Sciences

How to Measure Work of Adhesion and Surface Tension of Soft Materials

Tian, Yuan, TIAN

08 June 2018

No description available.

Physics

Polymers

Materials Science

work of adhesion

surface tension

MD simulation

networks

soft materials

HIERARCHICAL APPROACH TO PREDICTING TRANSPORT PROPERTIES OF A GRAMICIDIN ION CHANNEL WITHIN A LIPID BILAYER

WANG, ZHENG

January 2003

No description available.

Engineering, Chemical

molecular dynamics (MD) simulation

Gramicidin ion channel

Poisson-Nernst-Planck equation

Nernst-Einstein relation

Investigating Electrical Properties of Polycrystaline Silver Sulfide from Structure-Property Relation of Ag2S Paramorph

Shaulin, Tahrina Tanjim

24 July 2023

No description available.

Mechanical Engineering

Translocation of a Semiflexible Polymer Through a Nanopore

Adhikari, Ramesh

01 January 2015

The transport of a biomolecule through a nanopore occurs in many biological functions such as, DNA or RNA transport across nuclear pores and the translocation of proteins across the eukaryotic endoplasmic reticulum. In addition to the biological processes, it has potential applications in technology such as, drug delivery, gene therapy, and single molecule sensing. The DNA translocation through a synthetic nanopore device is considered as the basis for cheap and fast sequencing technology. Motivated by the experimental advances, many theoretical models have been developed. In this thesis, we explore the dynamics of driven translocation of a semiflexible polymer through a nanopore in two dimensions (2D) using Langevin dynamics (LD) simulation. By carrying out extensive simulation as a function of different parameters such as, driving force, length and rigidity of the chain, viscosity of the solvent, and diameter of the nanopore, we provide a detailed description of the translocation process. Our studies are relevant for fundamental understanding of the translocation process which is essential for making accurate nano-pore based devices.

Translocation

semiflexible polymer

nanopore

brownian dynamics simulation

langevin dynamics

polymer sequencing

md simulation

biophysics

soft matter physics

Physics

Investigation of the diffusion mechanisms of several hydrocarbons in the Metal-Organic-Framework Zn(tbip)

Seehamart, Kompichit

09 May 2011

Most of the computer simulations of molecules in Metal-Organic Frameworks (MOFs) to be found in the literature are done with rigid framework. But, Molecular Dynamics (MD) simulations of the self-diffusivity, Ds, of ethane within the one-dimensional 4.5 Å channels of the MOF type Zn(tbip)(H2 tbip = 5-tert-butyl isophthalic acid) presented in this work have shown not only quantitative, but also qualitative, differences in the Ds values for fixed and flexible lattices. Particularly, the dependence of Ds upon the concentration of molecules, c, is strongly influenced by the lattice flexibility. The reasons for this influence are investigated with the aid of probability density plots, free energy landscapes and barriers, along with a determination of the structural changes accompanying increasing c. It is found that for flexible lattices, the tighter, more constrained parts of the channels become wider at higher c; this allows more molecules to diffuse in the central region of the channels. The investigations for Zn(tbip) have been extended to three equimolar mixtures of ethane/ethane, CO2/ethane and CO2/methanol. The simulations take into account the lattice flexibility. The diffusional characteristics are discussed in relation to molecule properties and lattice geometry. The results show that Zn(tbip) may be a useful material for separating methane/ethane and CO2/ethane mixtures at low concentrations, and CO2/methanol mixtures at high concentrations. The temperature and concentration dependence of the self-diffusivity of propane diffusion in Zn(tbip) have been investigated as well by performing normal MD and hyper-MD with bias potential simulations. The obtained temperature dependence of the self-diffusivities is analyzed using an Arrhenius relationship, yielding the activation energy to be 9.53 kJ/mol and the pre-exponential factor to be 4.48×10-9 m2s-1. Using this hyper-MD method, interesting mechanisms of the propane molecules able to pass each other and exchange their sites in the channels can be observed. Because of mutual hindrance of propane molecules, the propane self-diffusivities decrease with increasing concentration.

MD-Simulation

Metall-Organische Gerüstverbindungen

Diffusion

flexibles Gitter

Self-diffusivity

Molecular dynamics

Framework flexibility

Mixture

Guest molecules

Metal-Organic Frameworks;

ddc:530

Structural and Dynamical Properties of Water and Polymers at Surfaces and Interfaces: A Molecular Dynamics Investigation

Bekele, Selemon

14 September 2018

No description available.

Polymers

Condensed Matter Physics

Materials Science

Nanoscience

MD simulation

molecular dynamics

oxidized surfaces

water contact angle

interfacial water

surfaces and interfaces

droplet spreading

Investigation of the diffusion mechanisms of several hydrocarbons in the Metal-Organic-Framework Zn(tbip)

Seehamart, Kompichit

05 April 2011

Most of the computer simulations of molecules in Metal-Organic Frameworks (MOFs) to be found in the literature are done with rigid framework. But, Molecular Dynamics (MD) simulations of the self-diffusivity, Ds, of ethane within the one-dimensional 4.5 Å channels of the MOF type Zn(tbip)(H2 tbip = 5-tert-butyl isophthalic acid) presented in this work have shown not only quantitative, but also qualitative, differences in the Ds values for fixed and flexible lattices. Particularly, the dependence of Ds upon the concentration of molecules, c, is strongly influenced by the lattice flexibility. The reasons for this influence are investigated with the aid of probability density plots, free energy landscapes and barriers, along with a determination of the structural changes accompanying increasing c. It is found that for flexible lattices, the tighter, more constrained parts of the channels become wider at higher c; this allows more molecules to diffuse in the central region of the channels. The investigations for Zn(tbip) have been extended to three equimolar mixtures of ethane/ethane, CO2/ethane and CO2/methanol. The simulations take into account the lattice flexibility. The diffusional characteristics are discussed in relation to molecule properties and lattice geometry. The results show that Zn(tbip) may be a useful material for separating methane/ethane and CO2/ethane mixtures at low concentrations, and CO2/methanol mixtures at high concentrations. The temperature and concentration dependence of the self-diffusivity of propane diffusion in Zn(tbip) have been investigated as well by performing normal MD and hyper-MD with bias potential simulations. The obtained temperature dependence of the self-diffusivities is analyzed using an Arrhenius relationship, yielding the activation energy to be 9.53 kJ/mol and the pre-exponential factor to be 4.48×10-9 m2s-1. Using this hyper-MD method, interesting mechanisms of the propane molecules able to pass each other and exchange their sites in the channels can be observed. Because of mutual hindrance of propane molecules, the propane self-diffusivities decrease with increasing concentration.

info:eu-repo/classification/ddc/530

ddc:530

Insights into Physical Aging of Thermally-Quenched and Solvent-Cast Polymers from Molecular Dynamics Simulation

Jaeger, Tamara D.

25 August 2020

No description available.

Condensed Matter Physics

Engineering

Polymers

physical aging

molecular dynamics simulation

polymer aging

solvent-processing

MD simulation

glasses

non-equilibrium dynamics

non-Arrhenius dynamics

Structure, Aggregation, and Inhibition of Alzheimer's B-Amyloid Peptide

Wang, Qiuming

28 August 2013

No description available.

Chemical Engineering

Alzheimer Disease

Beta-Amyloid peptide Abeta

Structure

Aggregation

Inhibition

Self-Assembled Monolayers SAMs

AFM

SPR

QSAR

MD simulation

Drug Design