A general strategy to develop cell permeable and fluorogenic probes for multicolour nanoscopy

It is difficult to develop suitable fluorescent probes for live-cell nanoscopy, but a general strategy is now reported that can transform regular fluorophores into fluorogenic probes with excellent cell permeability and low unspecific background signals. Using this approach, probes in a variety of colours were developed for different cellular targets and used for wash-free, multicolour, live-cell confocal and STED microscopy. Live-cell fluorescence nanoscopy is a powerful tool to study cellular biology on a molecular scale, yet its use is held back by the paucity of suitable fluorescent probes. Fluorescent probes based on regular fluorophores usually suffer from a low cell permeability and an unspecific background signal. Here we report a general strategy to transform regular fluorophores into fluorogenic probes with an excellent cell permeability and a low unspecific background signal. Conversion of a carboxyl group found in rhodamines and related fluorophores into an electron-deficient amide does not affect the spectroscopic properties of the fluorophore, but allows us to rationally tune the dynamic equilibrium between two different forms: a fluorescent zwitterion and a non-fluorescent, cell-permeable spirolactam. Furthermore, the equilibrium generally shifts towards the fluorescent form when the probe binds to its cellular targets. The resulting increase in fluorescence can be up to 1,000-fold. Using this simple design principle, we created fluorogenic probes in various colours for different cellular targets for wash-free, multicolour, live-cell nanoscopy.

A Guided Tour of Selected Image Processing and Analysis Methods for Fluorescence and Electron Microscopy

Michaël Unser

Microscopy imaging, including fluorescence microscopy and electron microscopy, has taken a prominent role in life science research and medicine due to its ability to investigate the 3D interior of live cells and organisms. A long-term research in bio-imaging at the sub-cellular and cellular scales consists then in inferring the relationships between the dynamics of macromolecules and their functions. In this area, image processing and analysis methods are now essential to understand the dynamic organization of groups of interacting molecules inside molecular machineries and to address issues in fundamental biology driven by advances in molecular biology, optics and technology. In this paper, we present recent advances in fluorescence and electron microscopy and we focus on dedicated image processing and analysis methods required to quantify phenotypes for a limited number but typical studies in cell imaging.

IEEE2016

Single molecule detection on surfaces

Marcel Leutenegger

Monitoring biological relevant reactions on the single molecule level based on fluorescence spectroscopy techniques has become one of the most promising approaches for understanding a variety of phenomena in biophysics, biochemistry and life science. By applying techniques of fluorescence spectroscopy to labeled biomolecules a manifold of important parameters becomes accessible. For example, molecular dynamics, energy transfer, and ligand-receptor reactions can be monitored at the molecular level. This huge application field was and still is a major drive for innovative optical methods as it opens the door for new quantitative insights of molecular interactions on a truly micro- and nano-scopic scale. This thesis contributes new single molecule detection (SMD) concepts, correlation analysis and optical correlation spectroscopy to study fluorophores or labeled biomolecules close to a surface. The search beyond the classical confocal volume towards improved confinement was a key objective. In a first approach, fluorescence correlation spectroscopy (FCS) using near field light sources to achieve highly confined observation volumes for detecting and measuring fluorophores up to micromolar concentration was investigated. In a second approach, FCS and fluorescence intensity distribution analysis (FIDA) based on dual-color total internal reflection fluorescence (TIRF) microscopy was conceived to achieve a common observation volume for dual-color fluorescence measurements. This resulted in two novel fluorescence fluctuation spectroscopy instruments providing observation volumes of less than 100al. The first instrument generates a near field observation volume around and inside nano-apertures in an opaque metal film. Back-illumination of such an aperture results in a highly confined excitation field at the distal aperture exit. This instrument was characterized with FCS and observation volumes as small as 30al were measured. The second instrument confines the observation volume with total internal reflection (TIR) at a glass-water interface. Today, the last-generation instrument provides a dual-color ps pulsed excitation and time-resolved detection for coincidence analysis and time-correlated single photon counting. It was characterized with FCS and FIDA and observation volumes of 70al to 100al were achieved. Moreover, the presence of the interface favors emission into the optically denser medium, such that nearly 60% of the emitted fluorescence can be collected. This very efficient light collection resulted in a two- to three-fold stronger fluorescence signal and led to a high signal to background ratio, which makes this instrument particularly suitable for SMD studies on surfaces. In parallel to these experimental investigations, a theoretical analysis of the total SMD process including an analysis of optical focus fields, molecule-interface interactions, as well as the collection and detection efficiency was performed. This analysis was used as a guideline for steady instrument improvements and for the understanding of the SMD process. Finally, SMD concepts were applied for a first investigation of in vitro expression of an odorant receptor and for monitoring the vectorial insertion into a solid-supported lipid membrane. These receptors were incorporated and immobilized in the lipid membrane. With increasing expression time, an increasing amount of receptors as well as an increasing aggregation was observed. The incorporation density and the receptor aggregation were investigated with TIRF microscopy and image correlation spectroscopy.

EPFL2007

The Colored Revolution of Bioimaging

François Aguet, Michaël Unser, Cédric René Jean Vonesch

With the recent development of fluorescent probes and new high-resolution microscopes, biological imaging has entered a new era and is presently having a profound impact on the way research is being conducted in the life sciences. Biologists have come to depend more and more on imaging. They can now visualize subcellular components and processes in vivo, both structurally and functionally. Observations can be made in two or three dimensions, at different wavelengths (spectroscopy), possibly with time-lapse imaging to investigate cellular dynamics. The observation of many biological processes relies on the ability to identify and locate specific proteins within their cellular environment. Cells are mostly transparent in their natural state and the immense number of molecules that constitute them are optically indistinguishable from one another. This makes the identification of a particular protein a very complex task—akin to finding a needle in a haystack. However, if a bright marker were attached to the protein of interest, it could very precisely indicate its position. Much effort has gone into finding suitable markers for this purpose, but it is only over the course of the past decade, with the advent of fluorescent proteins, that this concept has been revolutionized. These biological markers have the crucial properties necessary for dynamic observations of living cells: they are essentially harmless to the organism, and can be attached to other proteins without impacting their function. Fluorescence microscopy was invented almost a century ago, when microscopists were experimenting with ultraviolet light to achieve higher resolutions. In the very beginning, observations were limited to specimens that naturally fluoresce. Rapidly, fluorescent dyes for staining tissues and cells were investigated. But it was not until the 1940s that fluorescence microscopy became popular, when Coons and Kaplan introduced a technique to label antibodies with a fluorescent dye to study antibody-antigen interactions, profoundly changing the field of immunohistochemistry. The discovery that really brought fluorescence microscopy to the forefront came in 1994, when M. Chalfie et al. succeeded in expressing a naturally fluorescent protein, the now-famous green fluorescent protein (GFP), in living organisms. This was a landmark evolution in the field, fostering a whole new class of tagging methods. While genetic engineering is at the origin of this new methodology, a number of innovations from the fields of physics, optics, and mechanical and electrical engineering have been combined to provide the necessary instrumentation. Impressive enhancements in classical microscopy have been achieved, and new imaging systems are actively being developed. A key element for the evolution of microscopy in general was the shift to digital imaging in the 1990s, with the availability of affordable high-sensitivity acquisition devices and powerful computer hardware. The capabilities of today's systems often lead to enormous data sets that, in most cases, require postprocessing for their interpretation. Signal processing methods for biological research are only at their prelude; the needs are considerable and most probably not even clearly formulated yet. It is thus predictable that signal processing will be one of the main challenges of fluorescence microscopy in the forthcoming years. The goal of this article is to provide an overview of the main aspects of modern fluorescence microscopy. We first cover the principles of fluorescence and highlight the key discoveries in the history of fluorescence microscopy. In subsequent sections, we present the optics of fluorescence microscopes and examine various types of detectors. Finally, we discuss the signal and image processing challenges in fluorescence microscopy and highlight some of the present developments and future trends in the field.