X-RAY CRYSTALLOGRAPHY: Opening the Door to More Membrane Protein Structures

As recently as 10 years ago, the prospect of solving the structure of any membrane protein by X-ray crystallography seemed remote. Since then, the threedimensional (3-D) structures of two membrane protein complexes, the bacterial photosynthetic reaction centres of Rhodopseudomonas viridis (Deisenhofer et al. 1984, 1985) and of Rhodobacter sphaeroides (Allen et al. 1986, 1987 a, 6; Chang et al. 1986) have been determined at high resolution. This astonishing progress would not have been possible without the pioneering work of Michel and Garavito who first succeeded in growing 3-D crystals of the membrane proteins bacteriorhodopsin (Michel & Oesterhelt, 1980) and matrix porin (Garavito & Rosenbusch, 1980). X-ray crystallography is still the only routine method for determining the 3-D structures of biological macromolecules at high resolution and well-ordered 3-D crystals of sufficient size are the essential prerequisite.

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Beyond History: The List of The Most Well Studied Human Protein Structures

10.20944/preprints202008.0655.v1 ◽

2020 ◽

Author(s):

Zhenlu Li ◽

Matthias Buck

Keyword(s):

Protein Structures ◽

Protein Sequences ◽

Human Protein ◽

Current Status ◽

Protein Database ◽

X Ray ◽

X Ray Crystallography ◽

Protein Biophysics ◽

The Relationship ◽

Past Trend

Of 20,000 or so canonical human protein sequences, as of July 2020, 6,747 proteins have had their full or partial medium to high-resolution structures determined by x-ray crystallography or other methods. Which of these proteins dominate the protein database (the PDB) and why? In this paper, we list the 272 top protein structures based on the number of their PDB depositions. This set of proteins accounts for more than 40% of all available human PDB entries and represent past trend and current status for protein science. We briefly discuss the relationship which some of the prominent protein structures have with protein biophysics research and mention their relevance to human diseases. The information may inspire researchers who are new to protein science, but it also provides a year 2020 snap-shot for the state of protein science.

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Role of Computational Methods in Going beyond X-ray Crystallography to Explore Protein Structure and Dynamics

International Journal of Molecular Sciences ◽

10.3390/ijms19113401 ◽

2018 ◽

Vol 19 (11) ◽

pp. 3401 ◽

Cited By ~ 16

Author(s):

Ashutosh Srivastava ◽

Tetsuro Nagai ◽

Arpita Srivastava ◽

Osamu Miyashita ◽

Florence Tama

Keyword(s):

Protein Dynamics ◽

Computational Methods ◽

Protein Structures ◽

Three Dimensional ◽

Dimensional Structure ◽

X Ray ◽

X Ray Crystallography ◽

Insight Into

Protein structural biology came a long way since the determination of the first three-dimensional structure of myoglobin about six decades ago. Across this period, X-ray crystallography was the most important experimental method for gaining atomic-resolution insight into protein structures. However, as the role of dynamics gained importance in the function of proteins, the limitations of X-ray crystallography in not being able to capture dynamics came to the forefront. Computational methods proved to be immensely successful in understanding protein dynamics in solution, and they continue to improve in terms of both the scale and the types of systems that can be studied. In this review, we briefly discuss the limitations of X-ray crystallography in studying protein dynamics, and then provide an overview of different computational methods that are instrumental in understanding the dynamics of proteins and biomacromolecular complexes.

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Structure and function of cement proteins in human adenovirus

Acta Crystallographica Section A Foundations and Advances ◽

10.1107/s205327331408396x ◽

2014 ◽

Vol 70 (a1) ◽

pp. C1603-C1603

Author(s):

Vijay Reddy ◽

Glen Nemerow

Keyword(s):

Protein Structures ◽

Human Adenovirus ◽

Icosahedral Symmetry ◽

Virion Assembly ◽

X Ray ◽

X Ray Crystallography ◽

Capsid Shell ◽

Multiple Copies ◽

And Function ◽

Cement Protein

Human adenoviruses (HAdVs) are large (~150nm in diameter, 150MDa) nonenveloped double-stranded DNA (dsDNA) viruses that cause respiratory, ocular, and enteric diseases. The capsid shell of adenovirus (Ad) comprises multiple copies of three major capsid proteins (MCP: hexon, penton base and fiber) and four minor/cement proteins (IIIa, VI, VIII and IX) that are organized with pseudo T=25 icosahedral symmetry. In addition, six other proteins (V, VII, μ, IVa2, terminal protein and protease) are encapsidated along with the 36Kb dsDNA genome inside the capsid. The crystal structures of all three MCPs are known and so is their organization in the capsid from prior X-ray crystallography and cryoEM analyses. However structures and locations of various cement proteins are of considerable debate. We have determined and refined the structure of an entire human adenovirus employing X-ray crystallpgraphic methods at 3.8Å resolution. Adenovirus cement proteins play crucial roles in virion assembly, disassembly, cell entry and infection. Based on the refined crystal structure of adenovirus, we have determined the structure of the cement protein VI, a key membrane-lytic molecule and its associations with proteins V and VIII, which together glue peripentonal hexons beneath vertex region and connect them to rest of the capsid. Following virion maturation, the cleaved N-terminal pro-peptide of VI is observed deep in the peripentonal hexon cavity, detached from the membrane-lytic domain. Furthermore, we have significantly revised the recent cryoEM models for proteins IIIa and IX and both are located on the capsid exterior. Together, the cement proteins exclusively stabilize the hexon shell, thus rendering penton vertices the weakest links of the adenovirus capsid. Adenovirus cement protein structures reveal the molecular basis of the maturation cleavage of VI that is needed for endosome rupture and delivery of the virion into cytoplasm.

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Bence Jones KWR protein structures determined by X-ray crystallography

Acta Crystallographica Section D Biological Crystallography ◽

10.1107/s0907444907021981 ◽

2007 ◽

Vol 63 (7) ◽

pp. 780-792 ◽

Cited By ~ 7

Author(s):

Debora L. Makino ◽

Agnes H. Henschen-Edman ◽

Steven B. Larson ◽

Alexander McPherson

Keyword(s):

Protein Structures ◽

X Ray ◽

X Ray Crystallography

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xMDFF: molecular dynamics flexible fitting of low-resolution X-ray structures

Acta Crystallographica Section D Biological Crystallography ◽

10.1107/s1399004714013856 ◽

2014 ◽

Vol 70 (9) ◽

pp. 2344-2355 ◽

Cited By ~ 33

Author(s):

Ryan McGreevy ◽

Abhishek Singharoy ◽

Qufei Li ◽

Jingfen Zhang ◽

Dong Xu ◽

...

Keyword(s):

Molecular Dynamics ◽

Large Scale ◽

Protein Structures ◽

Data Bank ◽

Real Space ◽

Low Resolution ◽

X Ray ◽

X Ray Crystallography ◽

Atomic Structures ◽

Electron Density Map

X-ray crystallography remains the most dominant method for solving atomic structures. However, for relatively large systems, the availability of only medium-to-low-resolution diffraction data often limits the determination of all-atom details. A new molecular dynamics flexible fitting (MDFF)-based approach, xMDFF, for determining structures from such low-resolution crystallographic data is reported. xMDFF employs a real-space refinement scheme that flexibly fits atomic models into an iteratively updating electron-density map. It addresses significant large-scale deformations of the initial model to fit the low-resolution density, as tested with synthetic low-resolution maps of D-ribose-binding protein. xMDFF has been successfully applied to re-refine six low-resolution protein structures of varying sizes that had already been submitted to the Protein Data Bank. Finally,viasystematic refinement of a series of data from 3.6 to 7 Å resolution, xMDFF refinements together with electrophysiology experiments were used to validate the first all-atom structure of the voltage-sensing protein Ci-VSP.

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Visualisation of lipid features in membrane protein crystals by X-ray crystallography

Acta Crystallographica Section A Foundations of Crystallography ◽

10.1107/s0108767313096840 ◽

2013 ◽

Vol 69 (a1) ◽

pp. s365-s365

Author(s):

N. D. Drachmann

Keyword(s):

Membrane Protein ◽

Protein Crystals ◽

X Ray ◽

X Ray Crystallography

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Solving a new R2lox protein structure by microcrystal electron diffraction

Science Advances ◽

10.1126/sciadv.aax4621 ◽

2019 ◽

Vol 5 (8) ◽

pp. eaax4621 ◽

Cited By ~ 17

Author(s):

Hongyi Xu ◽

Hugo Lebrette ◽

Max T. B. Clabbers ◽

Jingjing Zhao ◽

Julia J. Griese ◽

...

Keyword(s):

Protein Structure ◽

Electron Diffraction ◽

Model Building ◽

Protein Structures ◽

X Ray Diffraction ◽

X Ray ◽

X Ray Crystallography ◽

Potential Map ◽

Metal Cofactor ◽

And Function

Microcrystal electron diffraction (MicroED) has recently shown potential for structural biology. It enables the study of biomolecules from micrometer-sized 3D crystals that are too small to be studied by conventional x-ray crystallography. However, to date, MicroED has only been applied to redetermine protein structures that had already been solved previously by x-ray diffraction. Here, we present the first new protein structure—an R2lox enzyme—solved using MicroED. The structure was phased by molecular replacement using a search model of 35% sequence identity. The resulting electrostatic scattering potential map at 3.0-Å resolution was of sufficient quality to allow accurate model building and refinement. The dinuclear metal cofactor could be located in the map and was modeled as a heterodinuclear Mn/Fe center based on previous studies. Our results demonstrate that MicroED has the potential to become a widely applicable tool for revealing novel insights into protein structure and function.

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MicroED structure of lipid-embedded mammalian mitochondrial voltage-dependent anion channel

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.2020010117 ◽

2020 ◽

Vol 117 (51) ◽

pp. 32380-32385

Author(s):

Michael W. Martynowycz ◽

Farha Khan ◽

Johan Hattne ◽

Jeff Abramson ◽

Tamir Gonen

Keyword(s):

Membrane Protein ◽

Focused Ion Beam ◽

Ion Beam ◽

Anion Channel ◽

Voltage Dependent Anion Channel ◽

X Ray ◽

X Ray Crystallography ◽

Voltage Dependent ◽

Viscous Media ◽

Scanning Electron

A structure of the murine voltage-dependent anion channel (VDAC) was determined by microcrystal electron diffraction (MicroED). Microcrystals of an essential mutant of VDAC grew in a viscous bicelle suspension, making it unsuitable for conventional X-ray crystallography. Thin, plate-like crystals were identified using scanning-electron microscopy (SEM). Crystals were milled into thin lamellae using a focused-ion beam (FIB). MicroED data were collected from three crystal lamellae and merged for completeness. The refined structure revealed unmodeled densities between protein monomers, indicative of lipids that likely mediate contacts between the proteins in the crystal. This body of work demonstrates the effectiveness of milling membrane protein microcrystals grown in viscous media using a focused ion beam for subsequent structure determination by MicroED. This approach is well suited for samples that are intractable by X-ray crystallography. To our knowledge, the presented structure is a previously undescribed mutant of the membrane protein VDAC, crystallized in a lipid bicelle matrix and solved by MicroED.

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