Model membranes as a tool for biological studies and biosensor applications

The biological membrane is a fundamental cellular structure which forms the natural selective barrier separating cells from their environment. Model membranes have long been employed to study these complicated structures in controlled environments. Within this dissertation we report the use of a defocused single molecule fluorescence imaging approach for examining the molecular level structure of model membranes which incorporate biological lipid components. Through these single molecule studies, an optimal single molecule probe of membrane structure was determined. Using this probe the influence of a minor biological membrane component, ganglioside GM1 (GM1), on membrane structure was examined. In addition to structural studies, we also report the use of model membranes as coatings for whispering gallery mode (WGM) label-free biosensors. Using Langmuir-Blodgett/Langmuir-Schaffer deposited bilayers we were able to demonstrate the specific detection of cholera toxin with a membrane containing the glycosphingolipid, GM1. Further studies of lipid coated WGM sensor showed polyethylene glycol (PEG) functionalized lipid bilayers are capable of reducing nonspecific adsorption on sensor surfaces while maintaining functional sites for specific analyte detection. Finally, preliminary studies for expanding the single molecule orientation approach to investigate antibody orientation on sensor surfaces are also reported. Through these studies the utility of both the defocused single molecule imaging technique and model membranes as a tool for biological and sensor applications is demonstrated

Ganglioside Influence on Phospholipid Films Investigated with Single Molecule Fluorescence Measurements

Single molecule fluorescence measurements are used to probe the effects of GM1 in DPPC monolayers. Langmuir-Blodgett films of GM1 and DPPC were doped with ~10−8 mol% of the fluorescent lipid probe, BODIPY-PC, and transferred onto glass substrates at 23 mN/m. As shown previously, the individual orientation of each BODIPY-PC probe in the membrane can be measured using defocused polarized total internal reflection fluorescence microscopy, revealing changes in film properties at the molecular level. Here, BODIPY-PC tilt angle histograms are used to characterize the effects of GM1 in DPPC films from 0.05 mol% to 100 mol% GM1. At high GM1 levels (>5 mol% GM1), trends in the single molecule measurements agree with previous bulk measurements showing the turnover from condensing to expanding influence of GM1 at ~20 mol%, thus validating the single molecule approach. At biologically relevant, low concentrations of GM1 (<5 mol% GM1), where bulk fluorescence measurements are less informative, the single molecule measurements reveal a marked influence of GM1 on film properties. The addition of trace amounts of GM1 to DPPC films leads to an expansion of the film which continues to 0.10 mol% GM1, above which the trend reverses and the condensing effect previously noted is observed

Integration of Microsphere Resonators with Bioassay Fluidics for Whispering Gallery Mode Imaging

Whispering gallery mode resonators are small, radially symmetric dielectrics that trap light through continuous total internal reflection. The resonant condition at which light is efficiently confined within the structure is linked with refractive index, which has led to the development of sensitive label-free sensing schemes based on whispering gallery mode resonators. One resonator design uses inexpensive high index glass microspheres that offer intrinsically superior optical characteristics, but have proven difficult to multiplex and integrate with the fluidics for sample delivery and fluid exchange necessary for assay development. Recently, we introduced a fluorescence imaging approach that enables large scale multiplexing with microsphere resonators, thus removing one obstacle for assay development. Here we report an approach for microsphere immobilization that overcomes limitations arising from their integration with fluidic delivery. The approach is an adaptation of a calcium-assisted glass bonding method originally developed for microfluidic glass chip fabrication. Microspheres bonded to glass using this technique are shown to be stable with respect to fluid flow and show no detectable loss in optical performance. Measured Q-factors, for example, remain unchanged following sphere bonding to the substrate. The stability of the immobilized resonators is further demonstrated by transferring lipid films onto the immobilized spheres using the Langmuir-Blodgett technique. Bilayers of DOPC doped with GM1 were transferred onto immobilized resonators to detect the binding of cholera toxin to GM1. Binding curves generated from shifts in the whispering gallery mode resonance result in a measured Kd of 1.5 × 10−11 with a limit of detection of 3.3 pM. These results are discussed in terms of future assay development using microsphere resonators

Single molecule probes of membrane structure: Orientation of BODIPY probes in DPPC as a function of probe structure

Single molecule fluorescence measurements have recently been used to probe the orientation of fluorescent lipid analogs doped into lipid films at trace levels. Using defocused polarized total internal reflection fluorescence microscopy (PTIRF-M), these studies have shown that fluorophore orientation responds to changes in membrane surface pressure and composition, providing a molecular level marker of membrane structure. Here we extend those studies by characterizing the single molecule orientations of six related BODIPY probes doped into monolayers of DPPC. Langmuir–Blodgett monolayers transferred at various surface pressures are used to compare the response from fluorescent lipid analogs in which the location of the BODIPY probe is varied along the length of the acyl chain. For each BODIPY probe location along the chain, comparisons are made between analogs containing phosphocholine and smaller fatty acid headgroups. Together these studies show a general propensity of the BODIPY analogs to insert into membranes with the BODIPY probe aligned along the acyl chains or looped back to interact with the headgroups. For all BODIPY probes studied, a bimodal orientation distribution is observed which is sensitive to surface pressure, with the population of BODIPY probes aligned along the acyl chains increasing with elevated surface pressure. Trends in the single molecule orientations for the six analogs reveal a configuration where optimal placement of the BODIPY probe within the acyl chain maximizes its sensitivity to the surrounding membrane structure. These results are discussed in terms of balancing the effects of headgroup association with acyl chain length in designing the optimal placement of the BODIPY probe

Book of Abstracts: 2019 Health Equity Summer Research Summit Organized by the Center of Excellence in Health Equity, Training and Research, Baylor College of Medicine, Houston, Texas 77030, USA on June 18th, 2019

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