FirstGlance/Virus Capsids and Other Large Assemblies

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Revision as of 18:52, 16 August 2022

Graphic Contents
Polio Virus 300 Å	Equine Encephalitis 644 Å	Clathrin Coat ≥725 Å
Vault Nanocompartment 650 Å		Gas Vesicle Up to 1 μm

Virus capsids and similarly large protein assemblies can be conveniently visualized and analyzed with FirstGlance in Jmol. Below some examples are explained and illustrated, but here is a quick start: polio virus capsid in FirstGlance (1pov).

FirstGlance in Jmol automatically constructs biological unit 1, thought to be the major functional quaternary assembly. Biological unit 1 is shown initially by default, and you can start separate sessions to show the asymmetric unit or other biological units when more than one are specified. When the resulting assembly is too large to work smoothly and efficiently in FirstGlance in Jmol (all Javascript), FirstGlance will automatically simplify the model to alpha carbons, or when necessary, to a subset of alpha carbons.

Most of the scenes below use color schemes that are built into FirstGlance, and are displayed very easily with just a few clicks of the mouse. The evolutionary conservation color scheme requires that the model be pre-processed by the ConSurf Server. It produces a PDB file understood by FirstGlance, which will automatically color the model by evolutionary conservation in its initial view.

1 Polio Virus
2 Eastern Equine Encephalitis Virus
- 2.1 Double-Shelled Capsid
- 2.2 Transmembrane Posts
3 Clathrin Coat
- 3.1 Amino and Carboxy Termini
- 3.2 Secondary Structure
4 Vault Nanocompartment
- 4.1 Evolutionary Conservation
- 4.2 Secondary Structure
5 Bacterial Gas Vesicle
- 5.1 Hydrophobic Inner Surface
- 5.2 Evolutionary Conservation

Polio Virus

Polio virus is small (among viruses pathogenic for humans) with an RNA genome inside a single-shell protein capsid. 1pov made up from 3 proteins, 60 copies of each of VP0, VP1 and VP3 (from proteolysis of polyprotein UniProt P03300)^[1]. 1pov provides the structure of the 3 chains in the asymmetric unit, along with instructions for constructing the capsid (Biological Unit 1)^[2].

The polio capsid has an icosahedral construction with 12 vertices defining 20 triangular faces. Notice that the larger blue mesas protruding on the surface have 5-fold symmetry. These are pentagonal capsomeres at the 12 vertices. The capsid is composed of 180 protein chains totaling about 377K non-H atoms.

Quick Start: polio virus capsid 1pov in FirstGlance

Measuring Capsid Diameter

FirstGlance/How To Measure A Virus Capsid provides step by step instructions on how to view a slab of the capsid and measure distances.

Color Schemes

(see caption). In addition to coloring by distance from the center, or assigning a distinct color to each group of sequence-identical chains, FirstGlance offers coloring by amino to carboxy rainbow, hydrophobic vs. polar, charge, and as illustrated below, evolutionary conservation.

Hide and Isolate

Hide and Isolate tools are provided in the Focus Box of FirstGlance. Clicking on a chain offers to hide or isolate all sequence-identical chains. Here, Similarly one can easily isolate or

Eastern Equine Encephalitis Virus

The (EEEV) consists of 240 copies of each of three distinct protein sequences, totaling 720 chains. It has nearly 2 million non-hydrogen atoms (so about 3.8 million atoms including hydrogen). The structure 6mx4 determined by electron microscopy (4.4 Å resolution) has 12 chains, with instructions for constructing the entire capsid using 60 copies of the asymmetric unit^[6].

Quick Start: EEEV capsid 6mx4 in FirstGlance

Double-Shelled Capsid

Immediately you can see that this is a double-layered capsid, with outer and inner shells. Between the shells are transmembrane alpha helical "spikes" or "posts" embedded in a lipid bilayer (not represented by any atoms here). FirstGlance/How To Measure A Virus Capsid provides step by step instructions on how to view a slab of the capsid and measure distances.

The inside diameter is about 315 Å. The length of the transmembrane spikes/posts is about 35 Å, consistent with the thickness of a lipid bilayer.

(total 720 protein chains).

Transmembrane Posts

When all ~242K alpha carbons (rather than every 10th) are displayed in FirstGlance, performance is sluggish, but more color schemes can be meaningfully applied.

Coloring alpha carbons in a slab by Hydrophobic, Polar reveals that the transmembrane posts are largely hydrophobic.

So, as expected, coloring the slab alpha carbons by charge Anionic (-) / Cationic (+) shows the posts to be nearly devoid of charges.

Clathrin Coat

This (3iyv), determined by electron microscopy at 7.9 Å resolution^[3], represents the clathrin lattice structure enveloping coated pits and coated vesicles. The deposited model contains only alpha carbons. It is about 725 by 665 Å. There are 184K alpha carbons, so it would have about three million atoms including hydrogens, with a molecular mass of about 21 MDa. 96% of the model is composed of 108 clathrin heavy chains, each of which models 1,630 of the 1,675 residues in UniProt P49951. , each modeled as 70 of 243 residues of UniProt P04973.

Quick Start: Clathrin Coat 3iyv in FirstGlance

Amino and Carboxy Termini

with its amino terminus blue and carboxy terminus red (with a spectal rainbow color sequence in between). When , it becomes evident that the carboxy termini are on the outside surface, while the amino termini form the inner surface.

Secondary Structure

Alpha Helices, Beta Strands , Loops
is nearly all beta sheets and loops, arranged as seven antiparallel 4-beta-strand sheets in a donut, forming a compact domain of 330 amino acids about 45 Å in diameter. The remaining 1,300 amino acids of the heavy chain form a "snake" about 460 Å long and roughly 20 Å thick. It is nearly all antiparallel alpha helices orthogonal to the long dimension. The 70 residues of the light chain present were modeled as helical. When the entire clathrin coat model is colored by secondary structure (NOT SHOWN), the outside surface is made of the alpha-helical "snakes", and the inner surface is lined with the amino-terminal beta-sheet donuts.

Vault Nanocompartment

occurs in eukaryotes. It is about 650 Å long and 380 Å wide. Its function is unknown^[4]. The vault is composed of 78 copies of a single protein sequence. This model has nearly one million atoms (including hydrogens), and 61K alpha carbons.

Quick Start: Vault 6bp8 in FirstGlance

Evolutionary Conservation

Quick Start: Vault with Conservation in FirstGlance (all 61K alpha carbons)

Conservation analysis was performed by ConSurf. In order for the pattern to be meaningful, all 61K alpha carbons were loaded into FirstGlance, which then applied the conservation colors.

Secondary Structure

amino-terminal portion consists of a series of small antiparallel beta sheet domains. A long alpha helix forms the carboxy-terminal portion.

Alpha Helices, Beta Strands , Loops

Take a closer look at the or the .

Here is the

Bacterial Gas Vesicle

"Gas vesicles allow a diverse group of bacteria and archaea to move in the water column by controlling their buoyancy. These gas-filled cellular nanocompartments are formed by up to micrometers long protein shells that are permeable only to gas."^[5] (7r1c). The actual nanocompartments are much longer, and taper down to conical caps at the ends.^[5] Actual gas vesicles vary in diameter, with some being about twice the diameter of this model.^[5] This model has 930 copies of a single protein sequence of 88 amino acids (GVpA, UniProt A0A0B6AAV2). It is 9 MDa with about 900K atoms including hydrogen and 60,450 alpha carbons. Actual gas vesicles can approach 1 μm in length with masses of hundreds of MDa^[5].

Quick Start: Gas Vesicle 7r1c in FirstGlance

Hydrophobic Inner Surface

The hydrophobic inside is thought to prevent the vesicle from filling with water (liquid or vapor).^[5]

Evolutionary Conservation

Evolutionary conservation of the amino acids in GVpA was determined by the ConSurf Server.

Quick Start: Evolutionary conservation of the gas vesicle in FirstGlance.

Possibly those conserved are involved in binding a stabilizing protein absent from this model, GVpC^[5]. Amino acids lining the inside surface are generally conserved, probably related to the ability of the vesicle to acquire gas selectively.

References

↑ Marsian J, Fox H, Bahar MW, Kotecha A, Fry EE, Stuart DI, Macadam AJ, Rowlands DJ, Lomonossoff GP. Plant-made polio type 3 stabilized VLPs-a candidate synthetic polio vaccine. Nat Commun. 2017 Aug 15;8(1):245. doi: 10.1038/s41467-017-00090-w. PMID:28811473 doi:http://dx.doi.org/10.1038/s41467-017-00090-w
↑ Basavappa R, Syed R, Flore O, Icenogle JP, Filman DJ, Hogle JM. Role and mechanism of the maturation cleavage of VP0 in poliovirus assembly: structure of the empty capsid assembly intermediate at 2.9 A resolution. Protein Sci. 1994 Oct;3(10):1651-69. PMID:7849583
↑ Brodsky FM. Cell biology: clathrin's Achilles' ankle. Nature. 2004 Dec 2;432(7017):568-9. doi: 10.1038/432568a. PMID:15577897 doi:http://dx.doi.org/10.1038/432568a
↑ Ding K, Zhang X, Mrazek J, Kickhoefer VA, Lai M, Ng HL, Yang OO, Rome LH, Zhou ZH. Solution Structures of Engineered Vault Particles. Structure. 2018 Mar 7. pii: S0969-2126(18)30054-6. doi:, 10.1016/j.str.2018.02.014. PMID:29551289 doi:http://dx.doi.org/10.1016/j.str.2018.02.014
↑ ^5.0 ^5.1 ^5.2 ^5.3 ^5.4 ^5.5 2022 Preprint: Cryo-EM structure of gas vesicles for buoyancy-controlled motility, by Stefan T. Huber, Dion Terwiel, Wiel H. Evers, David Maresca, and Arjen J. Jakobi. DOI 10.1101/2022.05.08.489936.
↑ Hasan SS, Sun C, Kim AS, Watanabe Y, Chen CL, Klose T, Buda G, Crispin M, Diamond MS, Klimstra WB, Rossmann MG. Cryo-EM Structures of Eastern Equine Encephalitis Virus Reveal Mechanisms of Virus Disassembly and Antibody Neutralization. Cell Rep. 2018 Dec 11;25(11):3136-3147.e5. doi: 10.1016/j.celrep.2018.11.067. PMID:30540945 doi:http://dx.doi.org/10.1016/j.celrep.2018.11.067

Proteopedia Page Contributors and Editors (what is this?)

Eric Martz, Karsten Theis

Retrieved from "http://52.214.119.220/wiki/index.php/FirstGlance/Virus_Capsids_and_Other_Large_Assemblies"

@@ Line 52: / Line 52: @@
 Virus capsids and similarly large protein assemblies can be conveniently visualized and analyzed with [[FirstGlance in Jmol]]. Below some examples are explained and illustrated, but here is a '''quick start''': [http://firstglance.jmol.org/fg.htm?mol=1pov polio virus capsid in FirstGlance] ([[1pov]]).
-FirstGlance in Jmol automatically constructs [[biological unit]] 1, thought to be the major functional quaternary assembly. [http://bioinformatics.org/firstglance/fgij4/notes.htm#bu Biological unit 1 is shown initially by default], and you can start separate sessions to show the [[asymmetric unit]] or other biological units when more than one are specified. When the resulting assembly is too large to work smoothly and efficiently in FirstGlance in Jmol (all Javascript), FirstGlance will [http://bioinformatics.org/firstglance/fgij4/notes.htm#simplification automatically simplify the model] to alpha carbons, or when necessary, to a subset of alpha carbons.
+FirstGlance in Jmol automatically constructs [[biological unit]] 1, thought to be the major functional quaternary assembly. [http://firstglance.jmol.org/notes.htm#bu Biological unit 1 is shown initially by default], and you can start separate sessions to show the [[asymmetric unit]] or other biological units when more than one are specified. When the resulting assembly is too large to work smoothly and efficiently in FirstGlance in Jmol (all Javascript), FirstGlance will [http://firstglance.jmol.org/notes.htm#simplification automatically simplify the model] to alpha carbons, or when necessary, to a subset of alpha carbons.
 Most of the scenes below use color schemes that are built into FirstGlance, and are displayed very easily with just a few clicks of the mouse. The evolutionary conservation color scheme requires that the model be pre-processed by the [[ConSurf/Index|ConSurf Server]]. It produces a PDB file understood by FirstGlance, which will automatically color the model by evolutionary conservation in its initial view.

FirstGlance/Virus Capsids and Other Large Assemblies

From Proteopedia

Revision as of 18:52, 16 August 2022

Contents

Polio Virus

Measuring Capsid Diameter

Color Schemes

Hide and Isolate

Eastern Equine Encephalitis Virus

Double-Shelled Capsid

Transmembrane Posts

Clathrin Coat

Amino and Carboxy Termini

Secondary Structure

Vault Nanocompartment

Evolutionary Conservation

Secondary Structure

Bacterial Gas Vesicle

Hydrophobic Inner Surface

Evolutionary Conservation

References

Proteopedia Page Contributors and Editors (what is this?)

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