Cryogenic electron microscopy (cryoEM) has become an indispensable technique for determining the structures of isolated biological macromolecules and imaging biomolecular structures within cells. While thin films of frozen-hydrated macromolecule suspensions can be directly prepared and imaged, these molecules must be extracted from their cellular context using existing sample preparation methods. On the other hand, cellular specimens preserve the native context, but the region of interest must be sectioned or subjected to focused ion-beam milling at cryogenic temperatures to achieve the necessary thickness for transmission electron imaging. Currently, no method exists for targeted cytoplasmic extraction of a subcellular volume from individual cells for direct vitrification and cryoEM imaging. In this study, a method is presented that addresses this gap. A system has developed that utilizes a force-sensitive microfluidic cantilever pipette to aspirate and dispense sample volumes as small as 204 fL onto conventional cryoEM sample supports, maintained at the dew point. This is followed by automatic vitrification for cryoEM imaging. Coupled with a fluorescence microscope, this setup allows for the extraction of a targeted subcellular volume from an individual cell and subsequent dispensing of the aspirated content onto an electron microscopy grid. A proof-of-concept is demonstrated by dispensing femtolitre volumes of the standard cryoEM single-particle sample, tobacco mosaic virus, and performing a subcellular biopsy from a single HeLa cell. Additionally, the challenges of manipulating such small volumes for cryoEM sample preparation are discussed, highlighting the current limitations of this approach and potential solutions for overcoming them.

Methylomirabilis bacteria perform anaerobic methane oxidation coupled to nitrite reduction via an intra-aerobic pathway, producing carbon dioxide and dinitrogen gas. These diderm bacteria possess an unusual polygonal cell shape with sharp ridges that run along the cell body. Previously, a putative surface protein layer (S-layer) was observed as the outermost cell layer of these bacteria. We hypothesized that this S-layer is the determining factor for their polygonal cell shape. Therefore, we enriched the S-layer from M. lanthanidiphila cells and through LC-MS/MS identified a 31 kDa candidate S-layer protein, mela_00855, which had no homology to any other known protein. Antibodies were generated against a synthesized peptide derived from the mela_00855 protein sequence and used in immunogold localization to verify its identity and location. Both on thin sections of M. lanthanidiphila cells and in negative-stained enriched S-layer patches, the immunogold localization identified mela_00855 as the S-layer protein. Using electron cryo-tomography and sub-tomogram averaging of S-layer patches, we observed that the S-layer has a hexagonal symmetry. Cryo-tomography of whole cells showed that the S-layer and the outer membrane, but not the peptidoglycan layer and the cytoplasmic membrane, exhibited the polygonal shape. Moreover, the S-layer consisted of multiple rigid sheets that partially overlapped, most likely giving rise to the unique polygonal cell shape. These characteristics make the S-layer of M. lanthanidiphila a distinctive and intriguing case to study.

We introduce a two-channel microfluidic atomic force microscopy (AFM) cantilever that combines the nanomechanical sensing functionality of an AFM cantilever with the ability to manipulate fluids of picolitres or smaller volumes through nanoscale apertures near the cantilever tip. Each channel is connected to a separate fluid reservoir, which can be independently controlled by pressure. Various systematic experiments with fluorescent liquids were done by either injecting the liquids from the on-chip reservoir or aspirating directly through the nanoscale apertures at the tip. A flow rate analysis of volume dosing, aspiration and concentration dosing inside the liquid medium was performed. To understand the fluid behaviour, an analytical model based on the hydrodynamic resistance, as well as numerical flow simulations of single and multi-phase conditions were performed and compared. By applying pressures between -500 mbar and 500 mbar to the reservoirs of the probe with respect to the ambient pressure, flow rates ranging from 10 fl s-1 to 83 pl s-1 were obtained inside the channels of the cantilever as predicted by the analytical model. The smallest dosing flow rate through the apertures was 720 fl s-1, which was obtained with a 10 mbar pressure on one reservoir and ambient pressure on the other. The solute concentration in the outflow could be tuned to values between 0% and 100% by pure convection and to values between 17.5% and 90% in combination with diffusion. The results prove that this new probe enables handling multiple fluids with the scope to inject different concentrations of analytes inside a single living cell and also perform regular AFM functionalities.

The steep increase of atomic scale structures determined by 3D cryo-electron microscopy (EM) deposited in the EMDataBank documents progress of a methodology that was frustratingly slow ten years ago. While sample vitrification on grids has been successfully used in all EM laboratories for decades, beam damage remains a road block. Developments in instrumentation and software to exploit the information carried by elastically scattered electrons made the task to achieve atomic scale resolution easier. This together with the development of fast single electron detecting cameras has resulted in unprecedented possibilities for structure determination by 3D cryo-EM. With such technologies in place, the purification of membrane protein complexes in a functional state is key to collecting atomic scale structural information and insight into the chemistry of physiological processes. Therefore, we focus here on the preparation of membrane proteins for structural analyses by 3D cryo-EM and the data acquisition of such vitrified samples.

Atomic force microscopy (AFM) is a powerful, multifunctional imaging platform that allows biological samples, from single molecules to living cells, to be visualized and manipulated. Soon after the instrument was invented, it was recognized that in order to maximize the opportunities of AFM imaging in biology, various technological developments would be required to address certain limitations of the method. This has led to the creation of a range of new imaging modes, which continue to push the capabilities of the technique today. Here, we review the basic principles, advantages and limitations of the most common AFM bioimaging modes, including the popular contact and dynamic modes, as well as recently developed modes such as multiparametric, molecular recognition, multifrequency and high-speed imaging. For each of these modes, we discuss recent experiments that highlight their unique capabilities.