A group theoretical approach to structural transitions of icosahedral quasicrystals and point arrays

Zappa, Emilio; Dykeman, Eric C.; Geraets, James A.; Twarock, Reidun

doi:10.1088/1751-8113/49/17/175203

Cited by 9 publications

(8 citation statements)

References 36 publications

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“…The Coxeter group D 6 embeds the icosahedral group H 3 as a subgroup (Kramer, 1993) and the exceptional Coxeter group E 8 embeds the non-crystallographic Coxeter group H 4 as a subgroup (Coxeter, 1973;Koca et al, 2001). It seems the affine extension of H 3 may play important roles in quasicrystals and in viral structures (Keef & Twarock, 2008;Indelicato et al, 2012;Dechant et al, 2013;Salthouse et al, 2015;Zappa et al, 2016). Structural transitions in quasicrystals induced by transitions in higher-dimensional lattices are discussed by Indelicato et al (2012).…”

Section: Introductionmentioning

confidence: 99%

From affine A ₄ to affine H ₂: group-theoretical analysis of fivefold symmetric tilings

Koca¹,

Koc²,

Koca³

et al. 2022

Acta Cryst Sect A

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The projections of lattices may be used as models of quasicrystals, and the particular affine extension of the H 2 symmetry as a subgroup of A 4, discussed in this work, presents a different perspective on fivefold symmetric quasicrystallography. Affine H 2 is obtained as the subgroup of affine A 4. The infinite discrete group with local dihedral symmetry of order 10 operates on the Coxeter plane of the root and weight lattices of A 4 whose Voronoi cells tessellate the 4D Euclidean space possessing the affine A 4 symmetry. Facets of the Voronoi cells of the root and weight lattices are identified. Four adjacent rhombohedral facets of the Voronoi cell V(0) of A 4 project into the decagonal orbit of H 2 as thick and thin rhombuses where long diagonals of the rhombohedra serve as reflection line segments of the reflection operators of H 2. It is shown that the thick and thin rhombuses constitute the finite fragments of the tiles of the Coxeter plane with the action of the affine H 2 symmetry. Projection of the Voronoi cell of the weight lattice onto the Coxeter plane tessellates the plane with four different tiles: thick and thin rhombuses with different edge lengths obtained from the projection of the square faces and two types of hexagons obtained from the projection of the hexagonal faces of the Voronoi cell. The structure of the local dihedral symmetry H 2 fixing a particular point on the Coxeter plane is determined.

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Section: Introductionmentioning

confidence: 99%

From affine A ₄ to affine H ₂: group-theoretical analysis of fivefold symmetric tilings

Koca¹,

Koc²,

Koca³

et al. 2022

Acta Cryst Sect A

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“…These gauge points indicate to the overall scaling of the point array. Another promising method of generating icosahedral point arrays has been offered by Zappa et al [11,12]. They propose generating point arrays from 6d projections of the hypercube.…”

Section: Introductionmentioning

confidence: 99%

Unveiling the Hidden Rules of Spherical Viruses Using Point Arrays

Wilson

2020

Viruses

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Since its introduction, the Triangulation number has been the most successful and ubiquitous scheme for classifying spherical viruses. However, despite its many successes, it fails to describe the relative angular orientations of proteins, as well as their radial mass distribution within the capsid. It also fails to provide any critical insight into sites of stability, modifications or possible mutations. We show how classifying spherical viruses using icosahedral point arrays, introduced by Keef and Twarock, unveils new geometric rules and constraints for understanding virus stability and key locations for exterior and interior modifications. We present a modified fitness measure which classifies viruses in an unambiguous and rigorous manner, irrespective of local surface chemistry, steric hinderance, solvent accessibility or Triangulation number. We then use these point arrays to explain the immutable surface loops of bacteriophage MS2, the relative reactivity of surface lysine residues in CPMV and the non-quasi-equivalent flexibility of the HBV dimers. We then explain how point arrays can be used as a predictive tool for site-directed modifications of capsids. This success builds on our previous work showing that viruses place their protruding features along the great circles of the asymmetric unit, demonstrating that viruses indeed adhere to these geometric constraints.

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“…The structural protrusions were found by classifying the viruses using our modified fitting methods [2,3] for icosahedral point arrays [4,5]. Point arrays provide highly specific geometric constraints on the arrangement of viral proteins, and all spherical viruses studied so far conform to one or more of these arrays [3][4][5][6][7][8][9][10][11][12][13][14]. We have previously shown that all protruding features of spherical viruses are located on the gauge points of these arrays, though it was not yet known that these locations also indicated the genomic composition.…”

Section: Introductionmentioning

confidence: 99%

Viral Phrenology

Wilson

Roof

2021

Viruses

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We introduce Viral Phrenology, a new scheme for understanding the genomic composition of spherical viruses based on the locations of their structural protrusions. We used icosahedral point arrays to classify 135 distinct viral capsids collected from over 600 capsids available in the VIPERdb. Using gauge points of point arrays, we found 149 unique structural protrusions. We then show how to use the locations of these protrusions to determine the genetic composition of the virus. We then show that ssDNA, dsDNA, dsRNA and ssRNA viruses use different arrangements for distributing their protrusions. We also found that Triangulation number is also partially dependent on the structural protrusions. This analysis begins to tie together Baltimore Classification and Triangulation number using point arrays.

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A group theoretical approach to structural transitions of icosahedral quasicrystals and point arrays

Cited by 9 publications

References 36 publications

From affine A ₄ to affine H ₂: group-theoretical analysis of fivefold symmetric tilings

From affine A ₄ to affine H ₂: group-theoretical analysis of fivefold symmetric tilings

Unveiling the Hidden Rules of Spherical Viruses Using Point Arrays

Viral Phrenology

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A group theoretical approach to structural transitions of icosahedral quasicrystals and point arrays

Cited by 9 publications

References 36 publications

From affine A 4 to affine H 2: group-theoretical analysis of fivefold symmetric tilings

From affine A 4 to affine H 2: group-theoretical analysis of fivefold symmetric tilings

Unveiling the Hidden Rules of Spherical Viruses Using Point Arrays

Viral Phrenology

Contact Info

Product

Resources

About

From affine A ₄ to affine H ₂: group-theoretical analysis of fivefold symmetric tilings

From affine A ₄ to affine H ₂: group-theoretical analysis of fivefold symmetric tilings