Jennifer Y. Chen

Two-Step Mechanism of Membrane Disruption by Aβ through Membrane Fragmentation and Pore Formation

Disruption of cell membranes by Aβ is believed to be one of the key components of Aβ toxicity. However, the mechanism by which this occurs is not fully understood. Here, we demonstrate that membrane disruption by Aβ occurs by a two-step process, with the initial formation of ion-selective pores followed by nonspecific fragmentation of the lipid membrane during amyloid fiber formation. Immediately after the addition of freshly dissolved Aβ(1-40), defects form on the membrane that share many of the properties of Aβ channels originally reported from single-channel electrical recording, such as cation selectivity and the ability to be blockaded by zinc. By contrast, subsequent amyloid fiber formation on the surface of the membrane fragments the membrane in a way that is not cation selective and cannot be stopped by zinc ions. Moreover, we observed that the presence of ganglioside enhances both the initial pore formation and the fiber-dependent membrane fragmentation process. Whereas pore formation by freshly dissolved Aβ(1-40) is weakly observed in the absence of gangliosides, fiber-dependent membrane fragmentation can only be observed in their presence. These results provide insights into the toxicity of Aβ and may aid in the design of specific compounds to alleviate the neurodegeneration of Alzheimers disease.

Probing the Sources of the Apparent Irreproducibility of Amyloid Formation: Drastic Changes in Kinetics and a Switch in Mechanism Due to Micellelike Oligomer Formation at Critical Concentrations of IAPP

The aggregation of amyloidogenic proteins is infamous for being highly chaotic, with small variations in conditions sometimes leading to large changes in aggregation rates. Using the amyloidogenic protein IAPP (islet amyloid polypeptide protein, also known as amylin) as an example, we show that a part of this phenomenon may be related to the formation of micellelike oligomers at specific critical concentrations and temperatures. We show that pyrene fluorescence can sensitively detect micellelike oligomer formation by IAPP and discriminate between micellelike oligomers from fibers and monomers, making pyrene one of the few chemical probes specific to a prefibrillar oligomer. We further show that oligomers of this type reversibly form at critical concentrations in the low micromolar range and at specific critical temperatures. Micellelike oligomer formation has several consequences for amyloid formation by IAPP. First, the kinetics of fiber formation increase substantially as the critical concentration is approached but are nearly independent of concentration below it, suggesting a direct role for the oligomers in fiber formation. Second, the critical concentration is strongly correlated with the propensity to form amyloid: higher critical concentrations are observed for both IAPP variants with lower amyloidogenicity and for native IAPP at acidic pH in which aggregation is greatly slowed. Furthermore, using the DEST NMR technique, we show that the pathway of amyloid formation switches as the critical point is approached, with self-interactions primarily near the N-terminus below the critical temperature and near the central region above the critical temperature, reconciling two apparently conflicting views of the initiation of IAPP aggregation.

Dissipation monitoring for assessing EGF-induced changes of cell adhesion

Epidermal growth factor (EGF)-induced cell de-adhesion has been implicated as a critical step of normal embryonic development, wound repair, inflammatory response, and tumor cell metastasis. Like many other cellular processes, this cell de-adhesion exhibits a complex, time-dependent pattern. A comprehensive understanding of this process requires a quantitative, real-time assessment of cell-substrate interactions at the molecular level. We employed the quartz crystal microbalance with dissipation monitoring (QCM-D) to successfully track the EGF-induced changes in energy dissipation factor, ΔD, of a monolayer of MCF10A cells in real time. This time-dependent ΔD response correlates well both qualitatively and quantitatively with sequential events of a rapid disassembly, transition, and slow reassembly of focal adhesions of the cells in response to EGF exposure. Based on this strong correlation, we utilized the QCM-D to demonstrate that this dynamic focal-adhesion restructuring is regulated temporally by the downstream pathways of EGFR signaling such as the PI3K, MAPK/ERK, and PLC pathways. Because the QCM-D is a noninvasive technique, this novel approach potentially has a broad range of applications in the fundamental study of cellular processes, such as cell signaling and trafficking and mechanotransduction, and holds promise for drug and biomarker screening.

Real-time and label-free detection of cellular response to signaling mediated by distinct subclasses of epidermal growth factor receptors.

Epidermal growth factor receptors (EGFRs) have often shown two distinct binding affinities for epidermal growth factor. It is the high-affinity EGFR that is predominantly responsible for mediating the cell signaling that plays an indispensable role in cell growth, proliferation, motility, and differentiation. We applied the quartz crystal microbalance with dissipation monitoring (QCM-D) to track short-term cellular responses to EGFR signaling in human carcinoma A431 cells. Cellular responses to high- and low-affinity EGFR signaling were detected individually as well as simultaneously based on changes in mass and viscoelasticity of cells. These responses are associated with EGF-induced biological processes including the cytoskeleton remodeling and calcium influx. QCM-D provides a label-free sensor technology that can be exploited to investigate the role of high-affinity EGFR in cancer development and cancer prognosis.

Characterization of mechanical behavior of an epithelial monolayer in response to epidermal growth factor stimulation

Cell signaling often causes changes in cellular mechanical properties. Knowledge of such changes can ultimately lead to insight into the complex network of cell signaling. In the current study, we employed a combination of atomic force microscopy (AFM) and quartz crystal microbalance with dissipation monitoring (QCM-D) to characterize the mechanical behavior of A431 cells in response to epidermal growth factor receptor (EGFR) signaling. From AFM, which probes the upper portion of an individual cell in a monolayer of cells, we observed increases in energy dissipation, Youngs modulus, and hysteresivity. Increases in hysteresivity imply a shift toward a more fluid-like mechanical ordering state in the bodies of the cells. From QCM-D, which probes the basal area of the monolayer of cells collectively, we observed decreases in energy dissipation factor. This result suggests a shift toward a more solid-like state in the basal areas of the cells. The comparative analysis of these results indicates a regionally specific mechanical behavior of the cell in response to EGFR signaling and suggests a correlation between the time-dependent mechanical responses and the dynamic process of EGFR signaling. This study also demonstrates that a combination of AFM and QCM-D is able to provide a more complete and refined mechanical profile of the cells during cell signaling.

Quartz Crystal Microbalance in Cell Biology Studies

In the past two decades, quartz crystal microbalance (QCM) has evolved from a simple mass sensor to a powerful bioanalytical tool that is capable of assessing the properties of complex biological materials including cells. This evolution has led to the emergence of applications of the QCM in cell research that are potentially relevant to fundamental cell biology, pharmaceutical development, medical diagnosis and prognosis, environmental analysis, etc. This review highlights some of the major advancements of QCM-based cell research and summarizes some of the technical advantages of the QCM that have impacted these advancements.

Quartz crystal microbalance: Sensing cell-substrate adhesion and beyond

Cell adhesion is an essential aspect of cellular behavior. Finding innovative methods to probe the adhesion of cells in their native state can greatly advance the understanding of control and regulation of cellular behavior and their impact on human health. The quartz crystal microbalance (QCM) is a label-free, biosensing system that has, in the past fifty years, evolved from a simple acoustic based mass sensor to a powerful bioanalytical tool. Its unique capability of monitoring the cell-substrate interaction non-invasively in real time has led to the emergence of its applications in areas that are relevant to fundamental cell biology and medical research. This review is intended to provide readers an overview of the use of the QCM for examination of cell-substrate adhesion. It also describes how this innovative approach can be extended to the study of other aspects of cellular behavior, such as cell morphology, cell mechanics, cell motility, cell signaling, all of which can potentially be applied to medical diagnosis and/or pharmaceutical development. In this review a major emphasis is placed on informing readers about some of the most important practical aspects of the QCM-based cell study including data acquisition and analysis, the substrate surface manipulation, and cell manipulation.

Effects of the expression level of epidermal growth factor receptor on the ligand-induced restructuring of focal adhesions: a QCM-D study

AbstractEpidermal growth factor receptor (EGFR) plays a major role in cell migration and invasion and is considered to be the primary source of activation of various malignant tumors. To gain insight into how elevated levels of EGFR influence cellular function, particularly cell motility, we used a quartz crystal microbalance with dissipation monitoring (QCM-D) to examine restructuring of focal adhesions in MCF-10A cells induced by epidermal growth factor. Engineered cells that overexpress epidermal growth factor receptor (EGFR) exhibited a very different kinetic profile from wildtype MCF-10A cells that have a lower level of EGFR with a higher rate for the initial disassembly of focal adhesion and a much lower rate for the later reassembly of focal adhesions. It is conceivable that these effects exhibited by EGFR-overexpressing cells may promote the initiation and maintenance of a more favorable adhesion state for cell migration. This study has demonstrated the capability of the dissipation monitoring function of the QCM-D to quantitatively assess kinetic aspects of cellular processes with a high temporal resolution and sensitivity. FigureCharacterization of the effects of the expression level of epidermal growth factor receptor on the kinetics of the epidermal growth factor-induced restructuring of focal adhesions with the quartz crystal microbalance with dissipation monitoring.

Dynamic Mechanical Response of Epithelial Cells to Epidermal Growth Factor

As a viscoelastic body, the cell exhibits both elastic and viscous characteristics (Kasza, 07). Although these mechanical properties have not been attributed wholly to a single element, such as the cytoskeletal network, the cytoplasm, the cell membrane, or the extracellular network (Janmey et al., 2007), it is agreed that they are determined predominantly by the cytoskeleton, a network of biopolymers in the form of actin filaments, microtubules, and intermediate filaments. The dynamic assembly and disassembly of these biopolymers give the cell the ability to move and to modulate its shape, elasticity, and mechanical strength in responses to mechanical and chemical stimuli from the external environment (Fletcher & Mullins, 2010). Among these cytoskeletal polymers, actin filaments are known to be primarily responsible for the rigidity of the cell. An increase in the concentration of actin filaments typically results in an increase in the rigidity of the cell, which can be characterized by Young’s modulus (Satcher Jr & Dewey Jr, 1996).

Evaluating Inhibition of the Epidermal Growth Factor (EGF)-Induced Response of Mutant MCF10A Cells with an Acoustic Sensor

Many cancer treatments rely on inhibition of epidermal growth factor (EGF)-induced cellular responses. Evaluating drug effects on such responses becomes critical to the development of new cancer therapeutics. In this report, we have employed a label-free acoustic sensor, the quartz crystal microbalance with dissipation monitoring (QCM-D), to track the EGF-induced response of mutant MCF10A cells under various inhibitory conditions. We have identified a complex cell de-adhesion process, which can be distinctly altered by inhibitors of signaling pathways and cytoskeleton formation in a dose-dependent manner. The dose dependencies of the inhibitors provide IC50 values which are in strong agreement with the values reported in the literature, demonstrating the sensitivity and reliability of the QCM-D as a screening tool. Using immunofluorescence imaging, we have also verified the quantitative relationship between the ΔD-response (change in energy dissipation factor) and the level of focal adhesions quantified with the areal density of immunostained vinculin under those inhibitory conditions. Such a correlation suggests that the dynamic restructuring of focal adhesions can be assessed based on the time-dependent change in ΔD-response. Overall, this report has shown that the QCM-D has the potential to become an effective sensing platform for screening therapeutic agents that target signaling and cytoskeletal proteins.