Biophysical studies of cholesterol in unsaturated phospholipid model membranes

Williams, Justin A.

January 2013

Indiana University-Purdue University Indianapolis (IUPUI) / Cellular membranes contain a staggering diversity of lipids. The lipids are heterogeneously distr ibuted to create regions, or domains, whose physical properties differ from the bulk membrane and play an essential role in modulating the function of resident proteins. Many basic questions pertaining to the formation of these lateral assemblies remain. T his research employs model membranes of well - defined composition to focus on the potential role of polyunsaturated fatty acids (PUFAs) and their interaction with cholesterol (chol) in restructuring the membrane environment. Omega - 3 (n - 3) PUFAs are the main bioactive components of fish oil, whose consumption alleviates a variety of health problems by a molecular mechanism that is unclear. We hypothesize that the incorporation of PUFAs into membrane lipids and the effect they have on molecular organization may be, in part, responsible. Chol is a major constituent in the plasma membrane of mammals. It determines the arrangement and collective properties of neighboring lipids, driving the formation of domains via differential affinity for different lipids . T he m olecular organization of 1 -[ 2 H 31 ]palmitoyl -2- eicosapentaenoylphosphatidylcholine (PEPC - d 31 ) and 1 -[ 2 H 31 ]palmitoyl -2- docosahexaenoylphosphatidylcholine (PDPC -d 31 ) in membran es with sphingomyelin (SM) and chol (1:1:1 mol) was compared by solid - state 2 H NMR spectroscopy. Eicosapentaenoic (EPA) and docosahexaenoic (DHA) acids are the two major n - 3 PUFAs found in fish oil, while PEPC -d 31 and PDPC -d 31 are phospholipids containing the respective PUFAs at the sn - 2 position and a perdeuterated palmitic acid a t the sn - 1 position . Analysis of s pectra recorded as a function of temperature indicate s that in both cases, formation of PUFA - rich (less ordered) and SM - rich (more ordered) domains occurred. A surprisingly substantial proportion of PUFA was found to infil trate the more ordered domain. There was almost twice as much DHA (65%) as EPA (30%) . The implication is that n - 3 PUFA s can incorporate into lipid rafts, which are domains enriched in SM and chol in the plasma membrane, and potentially disrupt the activity of signaling proteins that reside therein. DHA, furthermore, may be the more potent component of fish oil. PUFA - chol interactions were also examined through affinity measurements. A novel method utilizing electron paramagnetic resonance (EPR) was develope d, to monitor the partitioning of a spin - labeled analog of chol , 3β - doxyl - 5α - cholestane (chlstn), between large unilamellar vesicles (LUVs) and met hyl - β - cyclodextrin (mβCD). The EPR spectra for chlstn in the two environments are distinguishable due to the substantial differences in tumbling rates , allowing the population distribution ratio to be determined by spectral simulation. Advantages of this approach include speed of implementation and a vo idance of potential artifact s associated with physical separation of LUV and mβCD . Additionally, in a check of the method, t he relative partition coefficients between lipids measured for the spin label analog agree with values obtained for chol by isothermal titration calorimetry (ITC). Results from LUV with different composition confirmed a hierarchy of decreased sterol affinity for phospholipids with increasing acyl chain unsaturation , PDPC possessing half the affinity of the corresponding monounsaturated phospholipid. Taken together, the results of these studies on model membranes demonstrate the potential for PUFA - driven alteration of the architecture of biomembranes, a mechanism through which human health may be impacted.

Polyunsaturated Lipids

Cholesterol

EPA

DHA

Solid State Deuterium NMR

Membrane Domains

Cholestane

Unsaturated fatty acids -- Metabolism

Phospholipids -- Research

Cell membranes

Docosahexaenoic acid

Membranes (Biology)

Thermometric titration

Palmitic acid

Solid state physics -- Research

Deuterium

Unsaturated fatty acids -- Research

Sphingosine 1-phosphate enhances excitability of sensory neurons through sphingosine 1-phosphate receptors 1 and/or 3

Li, Chao

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Sphingosine 1-phosphate (S1P) is a bioactive sphingolipid that has proven to be an important signaling molecule both as an extracellular primary messenger and as an intracellular second messenger. Extracellular S1P acts through a family of five S1P receptors, S1PR1-5, all of which are G protein-coupled receptors associated with different G proteins. Previous work from our laboratory shows that externally applied S1P increases the excitability of small-diameter sensory neurons by enhancing the action potential firing. The increased neuronal excitability is mediated primarily, but not exclusively, through S1PR1. This raises the question as to which other S1PRs mediate the enhanced excitability in sensory neurons. To address this question, the expression of different S1PR subtypes in small-diameter sensory neurons was examined by single-cell quantitative PCR. The results show that sensory neurons express the mRNAs for all five S1PRs, with S1PR1 mRNA level significantly greater than the other subtypes. To investigate the functional contribution of other S1PRs in augmenting excitability, sensory neurons were treated with a pool of three individual siRNAs targeted to S1PR1, R2 and R3. This treatment prevented S1P from augmenting excitability, indicating that S1PR1, R2 and/or R3 are essential in mediating S1P-induced sensitization. To study the role of S1PR2 in S1P-induced sensitization, JTE-013, a selective antagonist at S1PR2, was used. Surprisingly, JTE-013 by itself enhanced neuronal excitability. Alternatively, sensory neurons were pretreated with FTY720, which is an agonist at S1PR1/R3/R4/R5 and presumably downregulates these receptors. FTY720 pretreatment prevented S1P from increasing neuronal excitability, suggesting that S1PR2 does not mediate the S1P-induced sensitization. To test the hypothesis that S1PR1 and R3 mediate S1P-induced sensitization, sensory neurons were pretreated with specific antagonists for S1PR1 and R3, or with siRNAs targeted to S1PR1 and R3. Both treatments blocked the capacity of S1P to enhance neuronal excitability. Therefore my results demonstrate that the enhanced excitability produced by S1P is mediated by S1PR1 and/or S1PR3. Additionally, my results indicate that S1P/S1PR1 elevates neuronal excitability through the activation of mitogen-activated protein kinase kinase. The data from antagonism at S1PR1 to regulate neuronal excitability provides insight into the importance of S1P/S1PR1 axis in modulating pain signal transduction.

sphingosine 1-phosphate

S1P

excitability

sensory neurons

G protein-coupled receptors

Sphingolipids -- Research

Excitation (Physiology)

Sensory neurons -- Research

Protein kinases

Cellular signal transduction

Phospholipids -- Research

G proteins -- Research

Neurochemistry

Second messengers (Biochemistry)

Cell interaction

Neural transmission

Developent of a Phospholipid Encapsulation Process for Quantum Dots to Be Used in Biologic Applications

Grimes, Logan

01 June 2014

The American Cancer Society predicts that 1,665,540 people will be diagnosed with cancer, and 585,720 people will die from cancer in 2014. One of the most common types of cancer in the United States is skin cancer. Melanoma alone is predicted to account for 10,000 of the cancer related deaths in 2014. As a highly mobile and aggressive form of cancer, melanoma is difficult to fight once it has metastasized through the body. Early detection in such varieties of cancer is critical in improving survival rates in afflicted patients. Present methods of detection rely on visual examination of suspicious regions of tissue via various forms of biopsies. Accurate assessment of cancerous cells via this method are subjective, and often unreliable in the early stages of cancer formation when only few cancer cells are forming. With fewer cancer cells, it is less likely that a cancer cell will appear in a biopsied tissue. This leads to a lower detection rate, even when cancer is present. This lack of detection when cancer is in fact present is referred to as a false negative. False negatives can have a highly detrimental effect on treating the cancer as soon as possible. More accurate methods of detecting cancer in early stages, in a nonsubjective form would alleviate these problems. A proposed alternative to visual examination of biopsied legions is to utilize fluorescent nanocrystalline biomarker constructs to directly attach to the abnormal markers found on cancerous tissues. Quantum dots (QDs) are hydrophobic nanoscale crystals composed of semiconducting materials which fluoresce when exposed to specific wavelengths of radiation, most commonly in the form of an ultraviolet light source. The QD constructs generated were composed of cadmium-selenium (CdSe) cores encapsulated with zinc-sulfide (ZnS) shells. These QDs were then encapsulated with phospholipids in an effort to create a hydrophilic particle which could interact with polar fluids as found within the human body. The goal of this thesis is to develop a method for the solubilization, encapsulation, and initial functionalization of CdSe/ZnS QDs. The first stage of this thesis focused on the generation of CdSe/ZnS QDs and the fluorescence differences between unshelled and shelled QDs. The second stage focused on utilizing the shelled QDs to generate hydrophilic constructs by utilizing phospholipids to bind with the QDs. Analysis via spectroscopy was performed in an effort to characterize the difference in QDs both prior to and after the encapsulation process. The method generated provides insight on fluorescence trends and the encapsulation of QDs in polar substances. Future research focusing on the repeatability of the process, introducing the QD constructs to a biological material, and eventual interaction with cancer cells are the next steps in generating a new technique to target and reveal skin cancer cells in the earliest possible stages without using a biopsy.

Quantum Dots

nanotechnology

nanotech

nano

bionanotechnology

biomarker

biomarkers

nanoparticles

fluorescent

nanocrystal

phospholipids

phospholipid

phosphocholine

CdSe

ZnS

Biochemical and Biomolecular Engineering

Bioimaging and Biomedical Optics

Biology and Biomimetic Materials

Biomaterials

Biotechnology

Ceramic Materials

Nanomedicine

Nanoscience and Nanotechnology

Other Chemical Engineering

Other Materials Science and Engineering

Semiconductor and Optical Materials

Interfacial structure of phospholipids probed by high-resolution, high-repetition-rate broadband vibrational sum-frequency generation spectroscopy

Yesudas, Freeda

20 December 2022

Diese Arbeit konzentriert sich auf die Anwendbarkeit eines hochmodernen 100 kHz BB-VSFG-Spektrometers, das kürzlich im SALSA Photonics Lab entwickelt wurde, für die Analyse der Grenzflächenstruktur von Alkylketten, des sie umgebenden Wassers und der Phosphatkopfgruppen von Phospholipidschichten. Zunächst wurden Phospholipid-Doppelschichten, die mehrere Komponenten enthalten, bei Laserwiederholraten von 5, 10, 50 und 100 kHz mit konstanter Pulsenergie untersucht. Die BB-VSFG-Spektren legen nahe, dass die Phospholipid-Doppelschichten während der Messungen ohne wärmeinduzierte Veränderungen stabil waren. Darüber hinaus bot die Erhöhung der Laserwiederholungsrate eine praktikable Möglichkeit, Spektren in kurzen Datenerfassungszeiten zu erhalten, ohne dass das Signal-Rausch-Verhältnis beeinträchtigt wurde. Die extrem kurze Aufnahmezeit von 500 ms, die hohe spektrale Auflösung und alle verwendeten Pulsparameter sorgen dafür, dass bei Messungen unter Umgebungsbedingungen keine thermisch bedingten Photoschäden auftreten. Es wurde eine systematische Untersuchung von ein- und zweikomponentigen Phospholipid-Monoschichten in Abhängigkeit von der Oberflächenspannung und dem Mischungsverhältnis für verschiedene Kombinationen an Polarisationen durchgeführt und die Abhängigkeit der Schwingungsspektren untersucht. Die Struktur von Alkylketten und umgebendem Wasser wurde anhand derselben Modellsystemen analysiert. Bislang nicht beobachtete Schwingungsbanden und Spektren von Monolagen mit geringer Oberflächenbedeckung wurden mit einem bisher nicht erreichten Signal-Rausch-Verhältnis gemessen und beschrieben. Die Struktur von Phospholipid-Monolagen mit identischen Kopfgruppen und unterschiedlichen Ketten wurde analysiert und verglichen. Die Spektren bestätigten die Anwesenheit von Wassermolekülen in der Nähe der Phosphat- und Cholingruppen der Phospholipid-Monolagen. / This thesis focuses on the applicability of a state-of-the-art 100 kHz BB-VSFG spectrometer recently developed at the SALSA Photonics Lab and on the analysis of the interfacial structure of alkyl chains, surrounding water, and the phosphate head groups of phospholipid layers. First, multi-component phospholipid bilayers were studied at laser repetition rates of 5, 10, 50, and 100 kHz at constant pulse energy. The spectra suggest that the phospholipid bilayers were stable during the measurements with no heat-induced distortions. Moreover, an increase in the laser repetition rate provided a feasible route to obtain spectra in short data acquisition times without compromising the signal-to-noise ratio. The extremely short acquisition time of 500 ms, the high spectral resolution, and all applied pulse parameters ensured no thermal induced photodamages occur during the measurements. A systematic study of one- and two-component phospholipid monolayers as a function of surface tension and mixture ratio at different polarization combinations was performed and the dependence of the vibrational spectra was explored. The structure of alkyl chains and surrounding water was analyzed using the same model systems. Vibrational modes that were previously unseen and spectra of monolayers at low surface coverage were reported for the first time with an unprecedented signal-to-noise ratio. The structure of phospholipid monolayers containing identical head groups and different chains was analyzed and compared. The order of the phospholipid molecules as a function of the composition of the monolayers was inferred from the spectral data. The influence of the hydration and/or changes in the orientation of the phosphate group was visible from the spectra as well.

Phospholipiden

Phospholipid-Monolagen

Phospholipid-Doppelschichten

100 kHz VSFG-Spektroskopie

high-resolution

high-repetition-rate

phospholipids

interfacial structure

bilayers

monolayers

100-kHz VSFG spectroscopy

541 Physikalische Chemie

VG 9307

VK 8527

WD 5400

ddc:541

Entwicklung molekularer Werkzeuge zur Erforschung des Lipidstoffwechsels / Synthese einer FRET-Sonde der sauren Sphingomyelinase

Pinkert, Thomas

11 July 2017

Im Rahmen dieser Arbeit wurden fluoreszierende Sphingomyelin-Analoga zu Studium der sauren Sphingomyelinase (ASM) synthetisiert. Ausgehend von L-Serin wurde ein Sphingosin-Derivat mit natürlicher Stereochemie dargestellt. Anschließend wurde mittels Phosphorodichloridat-Chemie eine Aminoethylphosphat-Gruppe installiert. Zweifache Fluoreszenzmarkierung ergab Sonden mit der Fähigkeit zu Förster-Resonanzenergietransfer (FRET). Diese wurden als Substrate der ASM akzeptiert und erlaubten die Verfolgung der Enzymaktivität in vitro. Durch die Analyse der photophysikalischen Eigenschaften der Fluorophore wurde das allgemeine Konzept der Phasentrennungs-gestützten Signalverstärkung (PS) abgeleitet. Dieses Konzept wurde erfolgreich bestätigt durch die Synthese einer 30-mal leistungsfähigeren zweiten Generation der FRET-Sonde. Ein homogener Assay wurde entwickelt, der die Quantifizierung der ASM-Aktivität erlaubte. Unter Verwendung von gereinigter rekombinanter humaner ASM, HeLa-Zelllysaten oder Lysaten von murinen embryonalen Fibroblasten (MEFs) als Enzymquelle wurde ausschließlich unter den von der ASM bevorzugten Bedingungen eine vollständige und spezifische Hydrolyse der Sonde beobachtet. Des Weiteren erlaubte die Sonde die Detektion relativer Unterschiede der Aktivität der ASM in kultivierten MEFs mittels Fluoreszenzmikroskopie mit Zweiphotonenanregung (2PE). / Fluorescent sphingomyelin analogues have been synthesized to probe the acid sphingomyelinase (ASM). Starting from L-serine, a sphingosine with natural stereochemistry was synthesized. Subsequently, phosphorodichloridate chemistry was used to install an aminoethyl phosphate moiety. Dual fluorescent labeling afforded probes capable of Förster resonance energy transfer (FRET). They were recognized as substrates of ASM and allowed for monitoring of the enzyme’s activity in vitro. Through analysis of the fluorophores’ photophysical properties, the general concept of partition aided amplification of a FRET probe’s signal (PS) was developed. This concept was successfully confirmed by the synthesis of a second-generation probe with 30-fold improved response. A homogenous assay was developed, which allowed for a quantitation of ASM activity. Using either purified recombinant human ASM, or lysates of HeLa cells or mouse embryonic fibroblasts (MEFs) as an enzyme source, complete and specific cleavage was observed exclusively under conditions preferred by ASM. Furthermore, the probe enabled the detection of relative levels of ASM activity in cultivated MEFs using fluorescence microscopy with two-photon excitation (2PE).

Enzyme

Saure Sphingomyelinas

Phospholipide

Sphingolipide

Sphingomyelin

Ceramid

Fluoreszenz

Förster-Resonanzenergietransfer (FRET)

Fluoreszenz-basierte Assays

Murine Embryonale Fibroblasten (MEF)

Zweiphotonenfluoreszenzmikroskopie

Enzymes

Acid Sphingomyelinase

Phospholipids

Sphingolipids

Sphingomyelin

Ceramide

Fluorescence

Fluorescence-based Assays

Mouse Embryonic Fibroblasts (MEF)

Two-photon Fluorescence Microscopy

547 Organische Chemie

VK 8707

WD 5050

VG 8757

ddc:547