Researchers from the Göttingen Cluster of Excellence Multiscale Bioimaging (MBExC) have uncovered the 3D structure of the ...

Scientists routinely create models of proteins using X-ray diffraction, nuclear magnetic resonance, and conventional cryo-electron microscope (cryoEM) imaging. But these models require computer ...

A recently developed technique called cryo-electron microscopy creates 3D visualizations of biological molecules like proteins, DNA, and RNA, making them visible in ways previously thought impossible.

They say a picture is worth a thousand words. But it takes millions of pictures to understand the intricate chemistry of an ...

Scientists have developed a new peroxidise-derived tag that can be used to label proteins for visualization by electron microscopy. The tag, called Apex, is a 28 kDa peroxidise that can withstand ...

Until now. Two laboratories recently used cryo-electron microscopy to directly image atoms in a protein molecule with a resolution of about 1.2 x 10-7 millimeters or 1.2 ångströms. The previous ...

and protein-nucleic acid complexes, across multiple universities and research disciplines, Erik brings valuable electron microscopy and laboratory experience to the BioKEM facility.

A collaboration between three labs at UC San Francisco has resulted in an unprecedented look at a member of a vital and ubiquitous class of proteins ... team used cryo-electron microscopy, a ...

including the discovery of new proteins and therapeutics and contributions made to the electronics revolution. But the field of electron microscopy must incorporate the latest advances in data science ...

Scientists routinely create models of proteins using X-ray diffraction, nuclear magnetic resonance, and conventional cryo-electron microscope (cryoEM) imaging. But these models require computer ...

Scientists routinely create models of proteins using X-ray diffraction, nuclear magnetic resonance, and conventional cryo-electron microscope (cryoEM) imaging. But these models require computer ...