Looking back and looking forward: contributions of electron microscopy to the structural cell biology of gametes and fertilization.

Mammalian gametes-the sperm and the egg-represent opposite extremes of cellular organization and scale. Studying the ultrastructure of gametes is crucial to understanding their interactions, and how to manipulate them in order to either encourage or prevent their union. Here, we survey the prominent electron microscopy (EM) techniques, with an emphasis on considerations for applying them to study mammalian gametes. We review how conventional EM has provided significant insight into gamete ultrastructure, but also how the harsh sample preparation methods required preclude understanding at a truly molecular level. We present recent advancements in cryo-electron tomography that provide an opportunity to image cells in a near-native state and at unprecedented levels of detail. New and emerging cellular EM techniques are poised to rekindle exploration of fundamental questions in mammalian reproduction, especially phenomena that involve complex membrane remodelling and protein reorganization. These methods will also allow novel lines of enquiry into problems of practical significance, such as investigating unexplained causes of human infertility and improving assisted reproductive technologies for biodiversity conservation.

Ultrastructural histochemistry in biomedical research: Alive and kicking.

The high-resolution images provided by the electron microscopy has constituted a limitless source of information in any research field of life and materials science since the early Thirties of the last century. Browsing the scientific literature, electron microscopy was especially popular from the 1970's to 80's, whereas during the 90's, with the advent of innovative molecular techniques, electron microscopy seemed to be downgraded to a subordinate role, as a merely descriptive technique. Ultrastructural histochemistry was crucial to promote the Renaissance of electron microscopy, when it became evident that a precise localization of molecules in the biological environment was necessary to fully understand their functional role. Nowadays, electron microscopy is still irreplaceable for ultrastructural morphology in basic and applied biomedical research, while the application of correlative light and electron microscopy and of refined ultrastructural histochemical techniques gives electron microscopy a central role in functional cell and tissue biology, as a really unique tool for high-resolution molecular biology in situ.

Unveiling the Extracellular Space of the Brain: From Super-resolved Microstructure to In Vivo Function.

The extracellular space occupies approximately one-fifth of brain volume, molding a spider web of gaps filled with interstitial fluid and extracellular matrix where neurons and glial cells perform in concert. Yet, very little is known about the spatial organization and dynamics of the extracellular space, let alone its influence on brain function, owing to a lack of appropriate techniques (and a traditional bias toward the inside of cells, not the spaces in between). At the same time, it is clear that understanding fundamental brain functions, such as synaptic transmission, memory, sleep, and recovery from disease, calls for more focused research on the extracellular space of the brain. This review article highlights several key research areas, covering recent methodological and conceptual progress that illuminates this understudied, yet critically important, brain compartment, providing insights into the opportunities and challenges of this nascent field.

Super-Resolution Microscopy: From Single Molecules to Supramolecular Assemblies.

Super-resolution microscopy (SRM) methods have allowed scientists to exceed the diffraction limit of light, enabling the discovery and investigation of cellular structures at the nanometer scale, from individual proteins to entire organelles. In this review we survey the application of SRM in elucidating the structure of macromolecules in the native cellular environment. We emphasize how SRM can generate molecular maps of protein complexes and extract quantitative information on the number, size, distribution, and spatial organization of macromolecules. We discuss both the novel information that can be generated through SRM as well as the experimental considerations to examine while conducting such studies. With the increasing popularity of SRM in the biological sciences, this review will serve as a tool to navigate the range of applications and harness the power of SRM to elucidate biological structures.

Update of technologies for examining the stratum corneum at the molecular level.

Understanding the molecular organization of the stratum corneum is still an outstanding problem, despite being both fundamentally and clinically significant. There is a need to develop methodology that yields molecular-level resolution of the stratum corneum components in their native state, without introducing artefacts. We outline here the recent success of cryo-electron microscopy of vitreous sections (CEMOVIS) combined with electron microscopy simulation to elucidate the molecular organization of the stratum corneum in its near-native state. Furthermore, some emerging technologies for studying the physical properties and dynamic behaviour of native stratum corneum at the molecular level are briefly reviewed. These encompass multiphoton microscopy (MPM), polarization transfer solid-state nuclear magnetic resonance (PTssNMR) and PeakForce tapping-mode atomic force microscopy combined with frequency-modulation Kelvin probe force microscopy (KPFM). CEMOVIS combined with electron microscopy simulation allows for molecular structure determination in situ in native stratum corneum, while MPM allows probing of the stratum corneum local physicochemical properties such as fluorophore diffusion coefficients, water content and pH. PTssNMR allows for evaluation of the molecular mobility of stratum corneum keratin and lipid components, and PeakForce KPFM allows for analysis of the local nanomechanical properties of stratum corneum. These emerging techno-logies may contribute to a molecular-level understanding of stratum corneum structure and function in vivo.

Is EM dead?

Since electron microscopy (EM) first appeared in the 1930s, it has held centre stage as the primary tool for the exploration of biological structure. Yet, with the recent developments of light microscopy techniques that overcome the limitations imposed by the diffraction boundary, the question arises as to whether the importance of EM in on the wane. This Commentary describes some of the pioneering studies that have shaped our understanding of cell structure. These include the development of cryo-EM techniques that have given researchers the ability to capture images of native structures and at the molecular level. It also describes how a number of recent developments significantly increase the ability of EM to visualise biological systems across a range of length scales, and in 3D, ensuring that EM will remain at the forefront of biology research for the foreseeable future.

The first years of the aberration-corrected electron microscopy century.

Aberration correction, after a 50 year incubation period of developing ideas and techniques while awaiting enabling technology, has transformed electron microscopy during the first dozen years of the 21st century. Some of the conditions that accompanied this transformation, the required complexity and its effect on the way microscopy is pursued, recent results that promise to change the field, and directions for the future are briefly described.

New information from large tissue volumes to the smallest structures of the cell: what new methods and electron microscopy can do for your research.

This article presents an overview of microscopy and its ability to assist in understanding what happens in cells and tissues. From the 1960s to 1980s, electron microscopy was the best way to understand cell processes, but the advent in the mid-1980s of light microscopy and the ability to do fluorescence imaging displaced electron microscopy in this area. However, the 21st century has seen several improvements in electron microscopy that, along with the need for more detailed ultrastructural information, make it again very attractive in the study of cells, tissues, and organs, and electron microscopy has resumed its place as the preeminent method in understanding cell processes.

Avances en la utilización de imágenes: microscopio digital y pico proyector / Developments in the utilization of images: digital microscope and pico projector

Existe una tendencia evolutiva hacia la digitalización de toda documentación: textos imágenes, sonidos. Toda esta documentación digitalizada puede ser presentada o expuesta mediante dispositivos digitales. Con el presente trabajo nos hemos propuesto dar a conocer los avances en la utilización de imágenes empleado el microscopio digital y el pico proyector digital, mencionando sus ventajas, desventajas, metodología y mostrando la experiencia inicial. Así tenemos que la digitalización de imágenes ha permitido la transferencia a medios de depósito o archivo. La observación de proceso fantástico que raya en lo mágico. Mientras que los proyectores digitales han sido un pilar sólido en la demostarción de material educativo, docente, investigación, u otro, su miniaturización ha revelado el ingenio humano

There is an evolutionary toward the digitalization of all documents, texts, images, sounds. All these documents can be scanned or exposed and presented by digital devices. With this work we intend to disclose developments in the use of images using the digital microscope and digital pico pocket projector, with their advantages, disadvantages, methodology and showing our initial experience. Thus, the digitization of images has allowed the tranfer to storege media or file. The observation of micro images and their immediate scanning is a great process that borders on the magic. While digital projectors have been a solid pillar in the proof of educational materials, teaching, research, or other, miniaturization has revealed human ingenuity

Current and future delivery of diagnostic electron microscopy in the UK: results of a national survey.

AIMS: Electron microscopy (EM) remains essential to delivering several specialist areas of diagnosis, especially the interpretation of native renal biopsies. However, there is anecdotal evidence of EM units struggling to survive, for a variety of reasons. The authors sought to obtain objective evidence of the extent and the causes of this problem. METHODS: An online survey was undertaken of Fellows of the Royal College of Pathologists who use EM in diagnosis. RESULTS: A significant number of EM units anticipate having to close and hence outsource their EM work in the coming years. Yet most existing units are working to full capacity and would be unable to take on the substantial amounts of extra work implied by other units outsourcing their needs. Equipment and staffing are identified by most EM units as the major barriers to growth and are also the main reasons cited for units facing potential closure. CONCLUSIONS: In the current financial climate it seems unlikely that units will be willing to make the large investment in equipment and staff needed to take on extra work, unless they can be reasonably confident of an acceptable financial return as a result of increased external referral rates. The case is thus made for a degree of national coordination of the future provision of this specialist service, possibly through the National Commissioning Group or the new National Commissioning Board. Without this, the future of diagnostic EM services in the UK is uncertain. Its failure would pose a threat to good patient care.

Imaging of protease functions--current guide to spotting cysteine cathepsins in classical and novel scenes of action in mammalian epithelial cells and tissues.

The human genome encodes some hundreds of proteases. Many of these are well studied and understood with respect to their biochemistry, molecular mechanisms of proteolytic cleavage, expression patterns, molecular structure, substrate preferences and regulatory mechanisms, including their endogenous inhibitors. Moreover, precise determination of protease localisation within subcellular compartments, peri- and extracellular spaces has been extremely useful in elucidating biological functions of peptidases. This can be achieved by refined methodology as will be demonstrated herein for the cysteine cathepsins. Besides localisation, it is now feasible to study in situ enzymatic activity at the various levels of subcellular compartments, cells, tissues, and even whole organisms including mouse.

[New applications and the comparison between atomic force microscope and electron microscope in regenerative medicine].

This article introduces the basic theories about atomic force microscope (AFM) and electron microscope (EM), respectively. New applications of each microscopic technology in regenerative medicine, covering both material science and life science, are discussed. The advantages or disadvantages of the kinds of microscopes in working conditions, sample preparation, resolution and the like, are discussed and compared systematically to make clear each scope of applications. This could be a useful guide for selecting the appropriate microscopic analysis in research work about regenerative medicine.