<i>Costumbres, Creencias, y “Lo normal”</i>: A Biocultural Study on Changing Prenatal Dietary Practices in a Rural Tourism Community in Costa Rica

Cantor, Allison Rachel

04 April 2016

This study explores the relationship between tourism, the nutrition transition, and prenatal dietary practices in the Monteverde Zone, Costa Rica. This rural tourism community, located in the central highlands of Costa Rica, has seen rapid growth and development since the tourism boom in the early 1990s, leading to changes in the local food system and increased food insecurity. This investigation added to this work by identifying the ways that prenatal dietary practices have shifted over time in the context of increased tourism and the concomitant nutrition transition, and by describing the relationship between food insecurity and nutritional status among pregnant women. In applying a critical biocultural approach, this study drew on both quantitative and qualitative methods. Pregnant women were recruited to participant in twenty-four hour diet recalls (n=21), the Household Food Insecurity and Access Scales (n=20), and semi-structured interviews (n=22). Women who had older children were also recruited for semi-structured interviews (n=20) to explore prenatal dietary practices and decision-making over time. Focus groups (N=2, n=15) and surveys with a free listing component (n=52) were administered to better understand the cultural construction of nutrition in this region, and how tourism and the nutrition transition have interacted with the local dietary norms. Overall this study found that there was a relationship between tourism, the nutrition transition, and diet, although findings suggest that pregnant women may be buffered from these effects by cultural factors. Food insecurity was present in the sample (n=7) and was associated with numerous variables, including saturated fat and zinc intake.

Nutrition transition

prenatal nutrition

critical biocultural approach

practice theory

Biological and Chemical Physics

Social and Cultural Anthropology

Rate Kinetics and Molecular Dynamics of the Structural Transitions in Amyloidogenic Proteins

Steckmann, Timothy Michael

01 January 2016

Amyloid fibril aggregation is associated with several horrific diseases such as Alzheimer’s, Creutzfeld-Jacob, diabetes, Parkinson’s and others. The process of amyloid aggregation involves forming myriad different metastable intermediate aggregates. Amyloid fibrils are composed of proteins that originate in an innocuous α-helix or random-coil structure. The α-helices convert their structure to β-strands that aggregate into β-sheets, and then into protofibrils, and ultimately into fully formed amyloid fibrils. On the basis of experimental data, I have developed a mathematical model for the kinetics of the reaction pathways and determined rate parameters for peptide secondary structural conversion and aggregation during the entire fibrillogenesis process from random coil to fibrils, including the molecular species that accelerate the conversions. The specific steps of the model and the rate constants that are determined by fitting to experimental data provide insight on the molecular species involved in the fibril formation process. To better understand the molecular basis of the protein structural transitions and aggregation, I report on molecular dynamics (MD) computational studies on the formation of amyloid protofibrillar structures in the small model protein ccβ, which undergoes many of the structural transitions of the larger, naturally occurring amyloid forming proteins. Two different structural transition processes involving hydrogen bonds are observed for aggregation into fibrils: the breaking of intrachain hydrogen bonds to allow β-hairpin proteins to straighten, and the subsequent formation of interchain hydrogen bonds during aggregation into amyloid fibrils. For my MD simulations, I found that the temperature dependence of these two different structural transition processes results in the existence of a temperature window that the ccβ protein experiences during the process of forming protofibrillar structures. Both the mathematical modeling of the kinetics and the MD simulations show that molecular structural heterogeneity is a major factor in the process. The MD simulations also show that intrachain and interchain hydrogen bonds breaking and forming is strongly correlated to the process of amyloid formation.

Steckmann

Gerstman

Chapagain

Rate

kinetics

molecular

dynamics

structural

transitions

amyloid

Biological and Chemical Physics

An Ethnographic Study: Becoming a Physics Expert in a Biophysics Research Group

Rodriguez, Idaykis

09 July 2013

Expertise in physics has been traditionally studied in cognitive science, where physics expertise is understood through the difference between novice and expert problem solving skills. The cognitive perspective of physics experts only create a partial model of physics expertise and does not take into account the development of physics experts in the natural context of research. This dissertation takes a social and cultural perspective of learning through apprenticeship to model the development of physics expertise of physics graduate students in a research group. I use a qualitative methodological approach of an ethnographic case study to observe and video record the common practices of graduate students in their biophysics weekly research group meetings. I recorded notes on observations and conduct interviews with all participants of the biophysics research group for a period of eight months. I apply the theoretical framework of Communities of Practice to distinguish the cultural norms of the group that cultivate physics expert practices. Results indicate that physics expertise is specific to a topic or subfield and it is established through effectively publishing research in the larger biophysics research community. The participant biophysics research group follows a learning trajectory for its students to contribute to research and learn to communicate their research in the larger biophysics community. In this learning trajectory students develop expert member competencies to learn to communicate their research and to learn the standards and trends of research in the larger research community. Findings from this dissertation expand the model of physics expertise beyond the cognitive realm and add the social and cultural nature of physics expertise development. This research also addresses ways to increase physics graduate student success towards their PhD. and decrease the 48% attrition rate of physics graduate students. Cultivating effective research experiences that give graduate students agency and autonomy beyond their research groups gives students the motivation to finish graduate school and establish their physics expertise.

Communities of Practice

identity

physics

graduate students

Biological and Chemical Physics

Higher Education

Other Physics

Science and Mathematics Education

Asymmetric Large Area Model Biomembranes

Liu, Paige

08 May 2020

All biological cell membranes maintain an electric transmembrane potential of around 100 mV, due in part to an asymmetric distribution of charged phospholipids across the membrane. This asymmetry is crucial to cell health and physiological processes such as intracell signaling, receptor-mediated endocytosis, and membrane protein conformation and function as well as active processes involving flippase and floppase proteins. Despite the biological significance, there are limited studies linking the consequences of lipid asymmetry to critical membrane properties and processes involving ion channels. One reason for this is the scarcity of reliable methods to create artificial membrane systems that incorporate both transverse lipid asymmetry and ion channels. Experimental artificial membrane systems incorporate essential cell membrane structures, namely the phospholipid bilayer, in a controllable manner where specific properties and processes can be isolated and examined in an environment much simpler than living systems. It is of particular interest to study asymmetry in transverse lipid composition across the phospholipid bilayer on such a system to probe the effects of the lipid composition and asymmetric arrangement of these lipids on the physicochemical properties of the membrane. By doing so, an understanding of how membrane asymmetry dictates membrane properties and in turn impacts cellular processes will be achieved. The primary goal of this thesis is to develop a platform for fabricating and characterizing compositionally controlled planar, free-standing, asymmetric membranes. This asymmetry was qualitatively demonstrated using a fluorescence quenching assay, and it has been quantified using a combination of anionic and zwitterionic lipids in concert with a patch-clamp amplifier system. Initial measurements of a transmembrane potential on a partially asymmetric bilayer were found to be between 10 and 25 mV. Increasing membrane charge asymmetry increases the offset voltage, as expected, and also modifies the stiffness of the membrane. These initial successes demonstrate a viable pathway to fabricate and quantitatively characterize asymmetric bilayers that can be extended to accommodate more complex membrane processes in the future.

membranes

material properties

electronic characterization

fluorescence assays

Biological and Chemical Physics

Complex Fluids

Membrane Science

Exploring the Complex Folding Free Energy Landscapes of a Series of β-rich Proteins

Cohen, Noah R.

11 September 2019

Protein aggregation is deleterious to human health and detrimental to therapeutic shelf-life. The physical processes that induce aggregation are the same processes that drive productive folding reactions. As such, protein aggregation is a non-productive form of protein folding. To gain insight into the steps that serve as a partition between the folding and aggregation reactions, the folding mechanisms of several β-rich proteins with links to human disease or medicine were examined. In the ALS-linked protein, SOD1, a subpopulation of the unfolded ensemble is found to be a common source of both nonnative structure and frustrated folding. These behaviors are only observed upon the reduction of the intrinsic disulfide bond, indicating that this covalent interaction wards against aggregation. The nonnative structure presents an attractive target for the development of new therapeutic agents. In VH domains from therapeutic mAbs, the intramolecular disulfide bond protects against aggregation. However, it can also introduce complexity to the folding mechanism. This complexity is linked to the formation of a strained orientation of the disulfide bond. This strained orientation of the disulfide in certain VH domains is energetically unfavorable enough to disrupt the formation of the disulfide in the full length mAbs. The novel relationship observed between disulfide orientation, folding complexity, and incomplete oxidation warrants further examination in other Ig domains. Overall, these results demonstrate that mapping the folding free energy landscape for proteins with roles in human disease or therapeutics can provide valuable insights for developing and improving treatment options.

Protein Folding

Aggregation

Disulfide Bonds

SOD1

ALS

Antibodies

Immunoglobulin Domains

Variable Domains

Biological and Chemical Physics

Biophysics

Alternating current studies and kinetic analysis of valinomycin mediated charge-transport through lipid bilayer membranes

Cox, Kenneth Lee

01 January 1984

In this study we have investigated the frequency dependence of bilayer lipid membranes for a series of glycerylmonoolein/ n-decane bilayers in various aqueous ionic solutions containing the ionophore valinomycin. Reliable values of membrane capacitance and conductance were obtained over the frequency range 0.2 - 200 KHz using an automatic balancing bridge under the control of a microprocessor unit. The admittance data was then normalized and curve-fitted to produce relaxation times and amplitudes from which the kinetic rate parameters, as deduced from a single slab dielectric membrane model, were calculated. These ac experimental rate constants were then compared with those obtained from charge-pulse relaxation methods.

Bilayer lipid membranes

Ion-permeable membranes

Glycerylmonooleate

Valinomycin

Ion exchange

Biological and Chemical Physics

Physics

Structure of Unmodified and Pyroglutamylated Amyloid Beta Peptide in Lipid Membranes

Hassan, Rowan

01 January 2021

Alzheimer's Disease (AD) is a devastating neurodegenerative disease that is characterized by brain atrophy, neuronal and synaptic loss, cognitive decline, trouble handling activities of daily life, and ultimately leads to death. Worldwide, at least 30 million people suffer from AD, with 5.8 million suffering in the US alone. Despite extensive basic and clinical research, the underlying molecular mechanisms behind AD remain largely unknown. There are four FDA-approved compounds are used for alleviating symptoms but have no curative potency. The first potentially disease-modifying AD drug, aducanumb, was approved by FDA in June 2021. The main histopathological traits of AD are the Amyloid-beta (Aβ) peptide and the tau protein. Aβ aggregates to form extracellular plaques in brain parenchyma and vasculature while tau forms intraneuronal tangles. Aβ is produced by enzymatic cleavage of the amyloid precursor protein (APP) in the brain. Once APP cleavage occurs, Ab monomers either aggregate extracellularly to form buildups of sticky plaque or embed themselves within the neuronal cell membrane to form pores, causing homeostatic dysregulation and eventually cell death. The mechanism of membrane pores formed by Ab and the pore structure remain to be characterized. This study aims to analyze the structure of four Aβ species in lipid membranes. These are the most abundant form of Aβ, Aβ1-40, and the more cytotoxic form, Aβ1-42, as well as their pyroglutamylated counterparts, pEAβ3-40 and pEAβ3-42, which are hypertoxic. These peptides have been studied using biophysical approaches, i.e., circular dichroism, fluorescence spectroscopy, and Fourier transform infrared spectroscopy. Elucidation of the structure of Aβ membrane pores provides valuable insight into the mechanism of Aβ toxicity and may help develop novel therapies for the lethal mystery that is AD.

Alzheimer's disease

Amyloid beta

FTIR

Pore formation

Biophysics

Beta barrel

Biological and Chemical Physics

Physics

The Spectrum of Cyclopentanone

Howard-Lock, Helen Elaine

09 1900

The infrared, Raman and ultraviolet spectra of cyclopentanone, cyclopentanone -α,α,α',α'-d₄ and cyclopentanone-d₈ have been studied. The high resolution ultraviolet absorption spectra of the three isotopic species have been analysed in detail. The electronic transition has been identified as a single-singlet transition associated with ṉ→π* orbital electron promotion. The vibrational and rotational structures accompanying this electronic transition have been analysed and the results are in agreement with theoretical predictions. The geometry of the molecule in both ground and excited states has been calculated. In the excited state conformation, the oxygen atom is bent out of the plane of the three adjacent carbon atoms; there is a potential barrier of 705cm⁻¹ with respect to the oxygen out-of-plane bending vibration in the upper state. / Thesis / Doctor of Philosophy (PhD)

chemical physics

infrared; Raman; ultraviolet; spectrum

Structure Difference and Implication to Assembly Morphology Control of Rous Sarcoma Virus Capsid Protein

Hastings, John

01 January 2019

Rous Sarcoma Virus (RSV) is an avian retrovirus with an enclosing capsid protein (CA) shell. RSV CA is studied due to its similar molecular structure to other retrovirus capsid proteins such as Human Immunodeficiency Virus (HIV). In this project, turbidity assay is used to track the assembly process of RSV CA, while solid state nuclear magnetic resonance (ssNMR) is used to probe the CA structure at a site specific level and investigate the morphology of the spherical structure of the I190V mutated strain of RSV CA. The I190V mutant is a naturally occurring mutation and is able to form into roughly uniform spheres, where the wild type RSV CA cannot form as pure spheres as possible. Turbidity assay results of the mutated RSV CA revealed a lack of a noticeable lag time before assembly began, as well as, a prolonged time period to reach saturation when compared to the wild-type RSV CA. Using ssNMR, and the TALOS-N program the torsion angles of the protein backbone were found. Using Ramachandran plots, it was found that the mutation of the 190th residue from Isoleucine to Valine caused a changed in the secondary structure of residues, from α-helix to β-sheet and vice versa. These changes were concentrated at the loops between select interfaces of helices that make up the structure of RSV CA. In particular, between helices 4 (residues 65-85), 8 (residues 165-177), and 11 (residues 215-225). The differing secondary structure in the mutant RSV CA was supported by the overlaying of the NMR spectra of the wild-type RSV CA on to the spherically assembled mutant RSV CA. It can be concluded that the spherical assembly of the mutated RSV CA displays noticeable differences in assembly and overall structure when compared to the wild-type RSV CA.

Biophysics

Protein

NMR

Assembly kinetics

protein structure

Biological and Chemical Physics

Physics

Synthesis and Characterization of Organic-Inorganic Hybrid Materials for Thermoelectric Devices

Huzyak, Paige M

01 April 2016

The development of organic-inorganic hybrid materials is of great interest in thermoelectrics for its potential to combine the desirable characteristics of both classes of materials. Thermoelectric materials must combine low thermal conductivity with high electrical conductivity, but in most materials, thermal and electrical conductivity are closely related and positively correlated. By combining the low thermal conductivity, flexibility, facile processing, and low cost of organic components with the high electrical conductivity and stability of inorganic components, materials with beneficial thermoelectric properties may be realized. Here, we describe the synthesis and characterization of anthracene-containing organic-inorganic hybrid materials for thermoelectric purposes. Specifically, POSS-ANT was synthesized when aminopropylisobutyl-POSS was functionalized with a single anthracene unit via DCC-mediated amide formation. Acrylate-POSS was functionalized with multiple anthracene units in a Heck coupling reaction to synthesize System 1. System 2 was developed through a two-step synthetic process. In the first reaction, (3- acryloxypropyl)methyl dimethyoxy silane was functionalized with anthracene at the 9- position through a Heck coupling reaction. The second reaction was a base-catalyzed solgel process to form polymeric nanoparticles. Finally, System 3 was synthesized through a similar process to System 2, though polymers formed in the initial step. The System 3 precursor was to be developed through a potassium carbonate-catalyzed ether synthesis from 3-(bromopropyl)trimethoxysilane and 9-anthracene methanol, followed by a basecatalyzed sol-gel process to form nanoparticles. The precursor was never isolated because of premature polymerization during the precursor synthesis step, and polymeric nanoparticles were obtained for System 3 during the sol-gel process. These materials were characterized by TEM to reveal the nanostructures that formed upon evaporation from solution. Future work will focus on the characterization of thermoelectric parameters and incorporation into thermoelectric devices.

organic synthesis

thermoelectricity

Acrylate-POSS

POSS-ANT

Biological and Chemical Physics

Chemistry

Inorganic Chemistry

Materials Chemistry

Organic Chemistry