Advances in Cryo-Electron Microscopy: Revolutionizing Molecular Imaging

Introduction

Cryo-electron microscopy (cryo-EM) is widely considered one of the most powerful techniques among those used in molecular imaging techniques; it provides high-resolution images and details of the structural biology of macromolecules. Ever since the evolution of cryo-EM in the last few decades, several developments in this field have transformed the way we see biological processes at the molecular level. Cryo-electron microscopy enables imaging of frozen-hydrated specimens and, therefore, reflects the biomolecular structures close to their native conformation; hence, cryo-EM is a powerful approach for the analysis of large complexes and proteins. This blog will discuss a few of the recent technological advancements in cryo-EM that have helped contribute to pushing the field into a new age of molecular imaging, both in terms of resolution and momentum.

The Evolution of Cryo-Electron Microscopy

After the introduction, cryo-EM has developed through various cycles that enhanced its resolution and applicability. Initial cryo-EM methodology performance was comparatively poor, mainly due to the achievable resolution hampered by technical issues in sample procurement, imaging, and data analysis. But over the years, cryo-EM has been aided by new techniques like direct electron detectors, phase plates, and more advanced image processing algorithms so that cryo-EM has been brought to the resolution levels of X-ray crystallography and nuclear magnetic resonance (NMR) spectroscopy.

It is not straightforward to highlight the most crucial advancements in cryo-EM, yet there is no doubt that direct electron detection cameras are among these advancements. In addition, these cameras have higher detective quantum efficiency (DQE), meaning that they can also produce high-quality images at low electron doses. Acquiring frames as movies has enhanced the precision of reconstructions by allowing the systems to perform motion correction and align the particles. This has enhanced cryo-EM to reach a sub-Voxel-level transformation resolution of about 2 Å, which enables the visualization of single atoms in biomolecular structures.

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The Role of Contrast Transfer Functions in Cryo-EM

Owing to its complexity, one of the central difficulties of cryo-EM has been the reliable estimation of contrast transfer functions (CTFs), which are used to quantify and correct distortions caused by the lenses of an electron microscope. CTF refinement has improved tremendously, with new algorithms like the CTFFIND4 that can estimate CTF a whole lot faster. This algorithm involves a mathematical model of the microscope’s optical system so that the contrast transfer function may be fitted to the amplitude spectrum of the images.

These new algorithms allow researchers to estimate defocus much more accurately, even in images that have been obtained using such state-of-the-art imaging tools as dose fractionation and phase plates. The precision of CTF modeling remains paramount for the higher resolution analysis of the biological specimen in cryo-EM, and these developments have enhanced cryo-EM’s capability to attain near-atomic resolution. Additionally, these methods have made data acquisition easier by producing images with a little blur that can easily be rectified through computational means, hence speeding the imaging process.

The Introduction of the Volta Phase Plate

The Volta phase plate (VPP) is another breakthrough development in cryo-EM as it improves image contrast while avoiding potential artifacts that may be introduced by the use of additional staining agents that could alter the state of the sample. The Volta phase plate functions by changing the phase of the electron wave that passes through the specimen, increasing the contrast of low-density objects such as proteins and viruses.

Real progress in cryo-EM imaging appeared with the advent of the so-called Volta phase plate with some amount of defocus. By optimizing Cs, this method provides an accurate measurement of and compensation for the contrast transfer function—high-contrast images without deleterious out-of-focus blur are attainable. Application of VPP together with defocus correction showed that cryo-EM can indeed reach resolutions of 2 Å, which were beyond the realm of such methods earlier.

Beam-Induced Motion Correction

Sample movement due to electron beam irradiation has always been a major challenge in cryo-EM since the beam used to image the sample also causes the sample to move. This motion can smoothen the surfaces and decrease the image resolution of the final reconstructed model. In the past, researchers had to address this effect in the only way possible: by reducing the electron dose with which they illuminated the sample, which led to low contrast in the resulting images.

Other advancements in motion correction techniques have dealt with this problem by following the motion of particles during acquisition. Another development was in processing the movies obtained from direct-electron detectors so that researchers were able to register frames of different individual particles and eliminate the motion caused by the beam. Such algorithms are intended to monitor the trajectory of several particles in the same visual field, thus making correction more accurate.

Moreover, scholars have tried dose-dependent approaches that regulate the quantity of detailed image data with radiation harm intensity. These models enable better structural information to be incorporated due to corrections of radiation damage in the sample. Therefore, this advancement opens the use of cryo-EM techniques to even smaller particles, giving biologists more sample types they can work with.

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High-Exposure Cryo-EM for Enhanced Image Quality

This manuscript has been of interest for quite a long time because finding an appropriate electron dose for imaging biological samples is challenging, given that excessive doses result in specimen damage, whereas low doses produce poor images. Research that has been conducted in the recent past has shown that using a higher exposure results in enhanced contrast and improved resolution of cryo-EM images of low-molecular-weight particles.

Tight regulation of the electron dose as well as subsequent image processing to delete images of low quality due to severe damage has allowed to obtain reconstructions of higher resolution. For small biological samples, this high exposure technique is particularly effective, where contrast is generally low in cryo-EM procedures. The new options of data collection technique with higher exposure have given the options for imaging of smaller and more vulnerable biological samples and have provided molecular biology with increased utility of cryo-EM.

The Cryo-EM “Resolution Revolution”

It is for this reason that cryo-EM proponents are dubbing this the “resolution revolution” due to the interplay of direct electron detectors, better phase plates, and algorithms. These advances have aided scientists in obtaining a resolution that was attainable with X-ray crystallography, where the crystalline structure of biological samples is necessitated—a feat that has proven challenging for many macromolecular complexes.

Some of the most spectacular of this resolution revolution include the imaging of large, flexible macromolecules at near-atomic resolution. This has in turn resulted in great findings in known areas of structure like the ribosome structure: researchers have used cryo-EM to obtain high-resolution images of the ribosomal subunits and other fundamental components of the cellular machinery. Whereas the method used to average only thousands of images for the reconstruction of the macromolecules, cryo-EM can now deliver images with 2 Å resolution, providing detailed information about their function.

The Broader Impact of Cryo-EM on Molecular Biology

Cryo-EM has significantly revolutionized the field of structural biology. Look at the example: It has become possible for researchers to investigate molecular machines in the context of their functions, observing dynamic events that were earlier difficult to photograph. During the years of its use, cryo-EM has made contributions to the understanding of the structures of viruses and their protein complexes and large molecular assemblies implicated in essential cell procedures and diseases.

Likewise, these technological advancements access the cryo-EM facility since the preparation and data acquisition have been made easier. Thus, with time and even more advancements in cryo-EM, the technique will become an even more essential tool for experimenting researchers in the field of structural biology and drug discovery.

Conclusion

Cryo-electron microscopy remains one of the rapidly growing fields of molecular imaging whereby biologists have an opportunity to study the biological macromolecules at the near-atomic level. These developments, including the direct electron detectors, the Volta phase plate, and the image processing algorithms, have put to an end many of the problems that had inhibited cryo-EM. These advancements serve not only the goal of enhancing the image quality but also contribute to extending the spectrum of specimens for further investigation using cryo-EM

Sooner or later, cryo-EM will bring a more significant contribution to understanding the molecular foundation of biological functions. With the help of cryo-EM, scientists can obtain images of ribosomal structures or high-resolution viral particle reconstructions to explain many phenomena occurring in molecular biology.

References

  1. Danev, R., Tegunov, D. and Baumeister, W., 2017. Using the Volta phase plate with defocus for cryo-EM single particle analysis. Elife6, p.e23006.
  2. Wu, S., Armache, J.P. and Cheng, Y., 2015. Single-particle cryo-EM data acquisition by using direct electron detection camera. Journal of Electron Microscopy65(1), pp.35-41.
  3. Rohou, A. and Grigorieff, N., 2015. CTFFIND4: Fast and accurate defocus estimation from electron micrographs. Journal of structural biology192(2), pp.216-221.
  4. Grant, T. and Grigorieff, N., 2015. Measuring the optimal exposure for single particle cryo-EM using a 2.6 Å reconstruction of rotavirus VP6. elife4, p.e06980.
  5. Scheres, S.H., 2014. Beam-induced motion correction for sub-megadalton cryo-EM particles. elife3, p.e03665.
  6. Kühlbrandt, W., 2014. The resolution revolution. Science343(6178), pp.1443-1444.
  7. Bai, X.C., Fernandez, I.S., McMullan, G. and Scheres, S.H., 2013. Ribosome structures to near-atomic resolution from thirty thousand cryo-EM particles. elife2, p.e00461.
  8. Typke, D., Downing, K.H. and Glaeser, R.M., 2004. Electron microscopy of biological macromolecules: bridging the gap between what physics allows and what we currently can get. Microscopy and Microanalysis10(1), pp.21-27.

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