Viola Mönkemöller

Open-source image reconstruction of super-resolution structured illumination microscopy data in ImageJ

Super-resolved structured illumination microscopy (SR-SIM) is an important tool for fluorescence microscopy. SR-SIM microscopes perform multiple image acquisitions with varying illumination patterns, and reconstruct them to a super-resolved image. In its most frequent, linear implementation, SR-SIM doubles the spatial resolution. The reconstruction is performed numerically on the acquired wide-field image data, and thus relies on a software implementation of specific SR-SIM image reconstruction algorithms. We present fairSIM, an easy-to-use plugin that provides SR-SIM reconstructions for a wide range of SR-SIM platforms directly within ImageJ. For research groups developing their own implementations of super-resolution structured illumination microscopy, fairSIM takes away the hurdle of generating yet another implementation of the reconstruction algorithm. For users of commercial microscopes, it offers an additional, in-depth analysis option for their data independent of specific operating systems. As a modular, open-source solution, fairSIM can easily be adapted, automated and extended as the field of SR-SIM progresses.

Multimodal super-resolution optical microscopy visualizes the close connection between membrane and the cytoskeleton in liver sinusoidal endothelial cell fenestrations

Liver sinusoidal endothelial cells (LSECs) act as a filter between blood and the hepatocytes. LSECs are highly fenestrated cells; they contain transcellular pores with diameters between 50 to 200 nm. The small sizes of the fenestrae have so far prohibited any functional analysis with standard and advanced light microscopy techniques. Only the advent of super-resolution optical fluorescence microscopy now permits the recording of such small cellular structures. Here, we demonstrate the complementary use of two different super-resolution optical microscopy modalities, 3D structured illumination microscopy (3D-SIM) and single molecule localization microscopy in a common optical platform to obtain new insights into the association between the cytoskeleton and the plasma membrane that supports the formation of fenestrations. We applied 3D-SIM to multi-color stained LSECs to acquire highly resolved overviews of large sample areas. We then further increased the spatial resolution for imaging fenestrations by single molecule localization microscopy applied to select small locations of interest in the same sample on the same microscope setup. We optimized the use of fluorescent membrane stains for these imaging conditions. The combination of these techniques offers a unique opportunity to significantly improve studies of subcellular ultrastructures such as LSEC fenestrations.

Imaging fenestrations in liver sinusoidal endothelial cells by optical localization microscopy

Liver sinusoidal endothelial cells (LSEC) are an important class of endothelial cells facilitating the translocation of lipoproteins and small molecules between the liver and blood. A number of clinical conditions, especially metabolic and aging-related disorders, are implicated by improper function of LSECs. Despite their importance, research into these cells is limited because the primary ultrastructures involved in their function are transcellular pores, called fenestrations, with diameters in a size range between 50-200 nm, i.e. well below the optical diffraction limit. Here, we show that we are able to resolve fenestrations with a spatial resolution of ∼20 nm by direct stochastic optical reconstruction microscopy (dSTORM). The cellular plasma membrane was labeled at high fluorophore density with CellMask Deep Red and imaged using a reducing buffer system. We compare the higher degree of structural detail that dSTORM provides to results obtained by 3D structured illumination microscopy (3D-SIM). Our results open up a path to image these physiologically important cells in vitro using highly resolving localization microscopy techniques that could be implemented on non-specialized fluorescence microscopes, enabling their investigation in most biomedical laboratories without the need for electron microscopy.

Nanoparticles as Nonfluorescent Analogues of Fluorophores for Optical Nanoscopy

Optical microscopy modalities that achieve spatial resolution beyond the resolution limit have opened up new opportunities in the biomedical sciences to reveal the structure and kinetics of biological processes on the nanoscale. These methods are, however, mostly restricted to fluorescence as contrast mechanism, which limits the ultimate spatial resolution and observation time that can be achieved by photobleaching of the fluorescent probes. Here, we demonstrate that Raman scattering provides a valuable contrast mechanism for optical nanoscopy in the form of super-resolution structured illumination microscopy. We find that nanotags, i.e., gold and silver nanoparticles that are capable of surface-enhanced Raman scattering (SERS), can be imaged with a spatial resolution beyond the diffraction limit in four dimensions alongside and with similar excitation power as fluorescent probes. The highly polarized nature of super-resolution structured illumination microscopy renders these nanotags elliptical in the reconstructed super-resolved images, which enables us to determine their orientation within the sample. The robustness of nanotags against photobleaching allows us to image these particles for unlimited periods of time. We demonstrate this by imaging isolated nanotags in a dense layer of fluorophores, as well as on the surface of and after internalization by osteosarcoma cells, always in the presence of fluorescent probes. Our results show that SERS nanotags have the potential to become highly multiplexed and chemically sensitive optical probes for optical nanoscopy that can replace fluorophores in applications where fluorescence photobleaching is prohibitive for following the evolution of biological processes for extended times.

Helium Ion Microscopy Visualizes Lipid Nanodomains in Mammalian Cells

Cell membranes are composed of 2D bilayers of amphipathic lipids, which allow a lateral movement of the respective membrane components. These components are arranged in an inhomogeneous manner as transient micro- and nanodomains, which are believed to be crucially involved in the regulation of signal transduction pathways in mammalian cells. Because of their small size (diameter 10-200 nm), membrane nanodomains cannot be directly imaged using conventional light microscopy. Here, direct visualization of cell membrane nanodomains by helium ion microscopy (HIM) is presented. It is shown that HIM is capable to image biological specimens without any conductive coating and that HIM images clearly allow the identification of nanodomains in the ultrastructure of membranes with 1.5 nm resolution. The shape of these nanodomains is preserved by fixation of the surrounding unsaturated fatty acids while saturated fatty acids inside the nanodomains are selectively removed. Atomic force microscopy, fluorescence microscopy, 3D structured illumination microscopy, and direct stochastic optical reconstruction microscopy provide additional evidence that the structures in the HIM images of cell membranes originate from membrane nanodomains. The nanodomains observed by HIM have an average diameter of 20 nm and are densely arranged with a minimal nearest neighbor distance of ≈ 15 nm.

A dystroglycan mutation (p.Cys667Phe) associated to muscle-eye-brain disease with multicystic leucodystrophy results in ER-retention of the mutant protein

Dystroglycan (DG) is a cell adhesion complex composed by two subunits, the highly glycosylated α‐DG and the transmembrane β‐DG. In skeletal muscle, DG is involved in dystroglycanopathies, a group of heterogeneous muscular dystrophies characterized by a reduced glycosylation of α‐DG. The genes mutated in secondary dystroglycanopathies are involved in the synthesis of O‐mannosyl glycans and in the O‐mannosylation pathway of α‐DG. Mutations in the DG gene (DAG1), causing primary dystroglycanopathies, destabilize the α‐DG core protein influencing its binding to modifying enzymes. Recently, a homozygous mutation (p.Cys699Phe) hitting the β‐DG ectodomain has been identified in a patient affected by muscle‐eye‐brain disease with multicystic leucodystrophy, suggesting that other mechanisms than hypoglycosylation of α‐DG could be implicated in dystroglycanopathies. Herein, we have characterized the DG murine mutant counterpart by transfection in cellular systems and high‐resolution microscopy. We observed that the mutation alters the DG processing leading to retention of its uncleaved precursor in the endoplasmic reticulum. Accordingly, small‐angle X‐ray scattering data, corroborated by biochemical and biophysical experiments, revealed that the mutation provokes an alteration in the β‐DG ectodomain overall folding, resulting in disulfide‐associated oligomerization. Our data provide the first evidence of a novel intracellular mechanism, featuring an anomalous endoplasmic reticulum‐retention, underlying dystroglycanopathy.

Optical nanoscopy to reveal structural and functional properties of liver cells (Presentation Recording)

The advent of optical nanoscopy has provided an opportunity to study fundamental properties of nanoscale biological functions, such as liver sinusoidal endothelial cells (LSEC) and their fenestrations. The fenestrations are nano-pores (50-200 nm) on the LSEC plasma membrane that allow free passage of molecules through cells. The fenestrated LSEC also hase a voracious appetite for waste molecules, viruses and nanoparticles. LSEC daily remove huge amounts of waste, nanoparticles and virus from the blood. Pharmaceuticals also need to pass through these fenestrations to be activated (e.g. cholesterol reducing statins) or detoxified by hepatocytes. And, when we age, our LSEC fenestrations become smaller and fewer. Today, we study these cells and structures using either conventional light microscopy on living cells, or high-resolution (but static) methods such as transmission and scanning electron microscopy on fixed (i.e. dead) tissue. Such methods, while very powerful, yield no real time information about the uptake of virus or nanoparticles, nor any information about fenestration dynamics. Therefore, to study LS-SEC, we are now using optical nanoscopy methods, and developing our own, to map their functions in 4 dimensions. Attaining this goal will shed new light on the cell biology of the liver and how it keeps us alive. This paper describes the challenges of studying LS-SEC with light microscopy, as well as current and potential solutions to this challenge using optical nanoscopy.

Label-free Super-resolution Optical Microscopy of Cellular Dynamics

We demonstrate super-resolved structured illumination microscopy (SR-SIM) of Raman-active samples with 100 nm spatial resolution. By combining SR-SIM with coherent Raman scattering, even biological samples can be visualized with doubled spatial resolution.