Biophysics of Blood Membranes

Himbert, Sebastian

11 1900

Red blood cells (RBCs) are the predominant cell type in blood and have a two-layered outer shell which is composed of a cytoskeleton network tethered to a cytoplasmic membrane. In this thesis, I study the structure and mechanical properties of the RBC’s cytoplasmic membrane (RBCcm) on the nanoscale and utilize this knowledge to functionalize this biological structure on a molecular level. In a first case study, I measure the membrane’s bending rigidity from thermal fluctuations observed in X-ray diffuse scattering (XDS) and Neutron Spin Echo (NSE) experiments, as well as Molecular Dynamics (MD) simulations. I provide evidence of the RBCcm's highly deformable nature with a bending rigidity that is substantially softer as compared to synthetic membranes. The methods are applied to RBCs that were stored for up to 5 weeks. I demonstrate that storage of RBCs leads to an increased fraction of liquid ordered membrane domains and an increased bending rigidity. RBCs are ideal for pharmaceutical applications as they provide access to numerous targets in the body, however lack specificity. Functionalizing the cytoplasmic membrane is thus a prerequisite to use these cells in biotechnology. I develop protocols throughout two studies to tune the membrane's lipid and protein composition. I investigate the impact of synthetic lipid molecules on the membrane's structure and demonstrate that small molecules can be encapsulated into liposomes that are formed from these hybrid membranes. Further, I provide direct evidence that the SARS-CoV 2 spike protein can be anchored into the RBCcm through a detergent mediated insertion protocol. These virus-like particles are observed to trigger seroconversion in mouse models, which demonstrates the potential of functionalized RBC in biotechnology. / Thesis / Doctor of Philosophy (PhD)

Blood

Membrane

Biophysics

Bending Modulus

Red Blood Cell Membrane

Covid 19

Functionalized Membranes

Hybrid Membranes

Assessment of Red Blood Cell Membrane Fatty Acid Composition in Relation to Dietary Intake in Patients Undergoing Cardiac Catheterization

Litwin, Nicole S

01 May 2014

Red blood cells (RBC) have been shown to mediate plaque development seen in coronary artery disease (CAD). This study determined whether differences in RBC fatty acid (FA) composition were related to CAD risk. FAs were extracted from RBCs of 38 individuals who have undergone cardiac catheterization, 9 of whom had obstructive CAD, and analyzed via gas chromatography. Ferric reducing ability of plasma (FRAP) assay was used to determine oxidative stress. Food frequency questionnaires were used to correlate RBC omega-3 FA to daily intake of omega-3 FA. No correlation was found between RBC content and intake of omega-3 FA. FRAP values and RBC FA composition did not differ between the 2 groups with exception of the saturated FA, palmitic acid (p=0.018). These results suggest that RBC FA composition may differ between individuals with or at risk for CAD. Additional research is needed to validate this biomarker as a predictor of CAD.

red blood cell membrane

fatty acid composition

omega-3 fatty acids

coronary artery disease

oxidative stress

Dietetics and Clinical Nutrition

Oxidative Stress, Dietary Fat Intake and Red Blood Cell Membrane Fatty Acid Composition in Women with and without Fertility Problems

Litwin, Nicole S., Assad, Norman A., Clark, W. Andrew, Ferrell, Tasha, Mohseni, Ray M., Zheng, Shimin

01 April 2015

No description available.

oxidative stress

dietary fat intake

red blood cell membrane

fatty acid composition

women

fertility

Biostatistics and Epidemiology

Allied Health Sciences

Dietetics and Clinical Nutrition

Public Health

Women's Health

Stereospecific dehydroxyfluorination and the synthesis of trifluoro D-hexose sugar analogues

Bresciani, Stefano

January 2011

This thesis describes stereospecific fluorination reactions, and addresses the synthesis of fluorosugars. In Chapter 1, the influence of fluorine on the physical properties of organic molecules, as well as its stereoelectronic effects, are introduced. Furthermore, an overview of nucleophilic and electrophilic fluorination reactions is given. Chapter 2 describes the dehydroxyfluorination of allylic alcohol diastereoisomers 155a and 155b, which can proceed either by direct or allylic fluorination. The regio- and stereo- selectivities were also assessed. Chapter 3 outlines the synthesis of the novel trifluoro D-glucose analogue 193 and trifluoro D-altrose analogue 216. The transport of these hexose analogues across the red blood cell membranes was then explored, to investigate the influence of polarity versus hydrogen bonding ability in carbohydrate-protein interactions. Chapter 4 describes the development and optimisation of Bio’s methodology, to promote stereospecific dehydroxyfluorination of benzylic alcohols (R)-213 and (R)-227 by addition of TMS-amine additives 226 and 229. And finally Chapter 5 reports the experimental procedures as well as the characterisation and the crystallographic data of the molecules prepared in this thesis.

547.02