Bengtsenhermansen4679

Cytoskeletal integrity is essential for neuronal complexity and functionality. Certain inherited neurological diseases are associated with mutated genes that directly or indirectly compromise cytoskeletal stability. While the large size and complexity of the neurons grown in culture poses certain challenges for imaging, live-cell imaging is an excellent approach to determine the morphological consequences of such mutants. This protocol details the use of spinning disk confocal microscopy and image analysis tools to evaluate branching and neurite length of healthy iPSC-derived glutamatergic neurons that express specific fluorescent proteins. The protocols can be adapted to neuronal cell lines of choice by the investigator.Multiphoton microscopy has provided us the ability to visualize cell behavior and biology in intact organs due to its superiority in reaching deep into tissues. Because skin draining lymph nodes are readily accessible via minimal surgery, it is possible to characterize the intricate interactions taking place in peripheral lymph nodes intravitally. Here we describe our protocol to visualize antigen-specific T cell-dendritic cell interactions in the popliteal lymph node of immunocompetent mice. With this method, behaviors of up to four cell types, such as T cells with different antigen specificities, T cells differentiated into different effector and regulatory lineages and dendritic cells originating from mice that bear mutations in functional genes can be imaged simultaneously.We describe a protocol for live-cell high-throughput (HTP) screening of yeast mutant strains carrying fluorescent protein markers for subcellular compartments of choice using automated confocal microscopy. This procedure, which combines HTP genetics and microscopy, results in the acquisition of thousands of images that can be analyzed in a systematic and quantitative way to identify morphology defects in the tagged subcellular compartments. This HTP protocol is readily adapted for screening any combination of markers and can be expanded to different growth conditions or higher order mutant genetic backgrounds.Eukaryotic phagocytes locate microorganisms via chemotaxis and consume them through phagocytosis. The social amoeba Dictyostelium discoideum is a stereotypical phagocyte and a well-established model to study both processes. PHA793887 Recent studies show that a G-protein-coupled receptor (fAR1) mediate a signaling network to control reorganization of the actin cytoskeleton leading both the directional cell movement and the engulfment of bacteria. Many live cell imaging methods have been developed and applied to monitor these signaling events. In this chapter, we will introduce how to measure GPCR-mediated signaling events for cell migration and phagocytosis in Dictyostelium.Macropinocytosis and phagocytosis are the processes by which eukaryotic cells use their plasma membrane to engulf liquid or a large particle and give rise to an internal compartment called the macropinosomes or phagosome, respectively. Dictyostelium discoideum provides a powerful system to understand the molecular mechanism of these two fundamental cellular processes that impact human health and disease. Recent developments in fluorescence microscopy allow direct visualization of intracellular signaling events with high temporal and spatial resolution. Here, we describe methods to visualize temporospatial activation or localization of key signaling components that are crucial for macropinocytosis and phagocytosis using confocal fluorescence microscopy.All eukaryotic cells are delimited by the plasma membrane, separating the cell from its environment. Two critical cellular pathways, the endocytic and the exocytic vesicle networks, shuttle material in and out the cell, respectively. The substantial development of cell biological imaging techniques, along with improved fluorescent probes and image analysis tools, has been instrumental in increasing our understanding of various functions and regulatory mechanisms of various intracellular vesicle subpopulations and their dynamics. Here, using B lymphocytes (B cells) as a model system, we provide a protocol for 3D analysis of the intracellular vesicle traffic in either fixed or living cells using spinning disk confocal microscopy. We also describe the usage of image deconvolution to improve the resolution, particularly important for vesicular networks in lymphocytes due to the small size of these cells. Lastly, we describe two types of quantitative analysis vesicle distribution/clustering toward the microtubule organizing center (MTOC), and colocalization analysis with endolysosomal markers.High-resolution confocal imaging has provided new insights in the process of receptor-mediated endocytosis in variety of cell types. We describe here the protocol for investigating B cell receptor (BCR)-mediated internalization of membrane bound antigens using confocal microscopy. We describe the method to prepare plasma membrane sheets (PMS) in a small area, bind fluorescently tagged antigens to the PMS and activate B cells on the PMS. We also describe the method for analyzing antigen internalization using confocal microscopy and computational image analysis. This protocol is useful for the study of antigen internalization by B cells and can be applied for studying receptor-mediated endocytosis in other cells as well. The setup we describe here is especially useful for studying rare cell types when the number of cells available is limiting.Expansion microscopy (ExM) is a method to expand biological specimens ~fourfold in each dimension by embedding in a hyper-swellable gel material. The expansion is uniform across observable length scales, enabling imaging of structures previously too small to resolve. ExM is compatible with any microscope and does not require expensive materials or specialized software, offering effectively sub-diffraction-limited imaging capabilities to labs that are not equipped to use traditional super-resolution imaging methods. Expanded specimens are ~99% water, resulting in strongly reduced optical scattering and enabling imaging of sub-diffraction-limited structures throughout specimens up to several hundred microns in (pre-expansion) thickness.