molecules in wonderland of crystallographyoverview molecules in wonderland of crystallography...
TRANSCRIPT
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Overview
Molecules in Wonderlandof Crystallography
Dedicated to the 70th anniversary of Peter Wyder, Emeritus
1. Introduction
2. Growth form lattices Snow flakes
3. Molecular form lattices Proteins
4. Polygonal lattices and polygrams Pentagonal case
5. Pentagonal proteins Cyclophilin, D-aminopeptidase
6. Decagonal DNA B-DNA
7. Integral lattices Frank’s ’cubic’ hexagonal lattice
8. Conclusions
Stuttgart, Max-Planck Institute, 16.03.04 A. Janner
. – p.1/35
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alice
Alice’s adventures in wonderland
. – p.2/35
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magnet
Peter’s adventures in wonderland
. – p.3/35
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mignon
(Sci.Am. 2)
Kennst du das Wunderland,
Wo Moleküle die Schneeflockengleichen,
Kennst du es wohl?
. – p.4/35
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Cryst+Growt latt. (SA) [SAa]
Ice and Snow Flake: Microscopic and Macroscopic Lattices
Crystal lattice Growth lattice
Ch. and N. Knight, Scientific American (1973) 100-107 . – p.5/35
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Sa1+Sa2[SAb]
Hexagrammal Scaling Symmetry of Snow Crystals
Facet-like snow flake Dendric-like snow flake
(Sci.Am. 2) (Sci.Am. 1)
Scientific American (1961)
Hexagrammal Scaling Symmetry of Snow CrystalsMid-edge star hexagons: λME = 1/2 Vertex star hexagons: λV E = 1/
√
3
(Sci.Am. 2) (Sci.Am. 1)
. – p.6/35
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Sa1+Sa2[SAb]
Hexagrammal Scaling Symmetry of Snow Crystals
Facet-like snow flake Dendric-like snow flake
(Sci.Am. 2) (Sci.Am. 1)
Scientific American (1961)
Hexagrammal Scaling Symmetry of Snow CrystalsMid-edge star hexagons: λME = 1/2 Vertex star hexagons: λV E = 1/
√
3
(Sci.Am. 2) (Sci.Am. 1)
. – p.6/35
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Indexed starhex. vert.
(ls5/decacg33)
Indexed Star Hexagon
Vertex Scaling Relations
Scaling: Rotation:1 / √3 π / 6
3 -3
6 3
3 6
-3 3
-6 -3
-3 -6
1 -1
2 1
1 2
-1 1
-2 -1
-1 -2
3 0
3 30 3
-3 0
-3 -3 0 -3
1 0
1 10 1
-1 0
-1 -1 0 -1
(2 -1)
(1 1)(-1 2)
(-2 1)
(-1 -1) (1 -2)
(2 -1)
(1 1)(-1 2)
(-2 1)
(-1 -1) (1 -2)
(1 0)
(0 1)
(1 -1)
(-1 0)
(0 -1)
(1 -1)
. – p.7/35
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Indexed hexagram
Indexed Star Hexagon
mid-edge scaling relations
8,0
8,8
0,8
-8,0
-8,-8
0,-8
4,0
4,4
0,4
-4,0
-4,-4
0,-4
2,0
2,2
0,2
-2,0
-2,-2
0,-2
1,0
1,10,1
-1,0
-1,-10,-1
(1,0)
(0,1)(-1,1)
(-1,0)
(0,-1) (1,-1)
(1,0)
(0,1)
(1,-1)
. – p.8/35
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Olovsson
A Sample of Snow Flakes
An hyperbolic hexagon as growth form?
. – p.9/35
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olov-46a (fig1a)
Snow Crystals with Flat and Hyperbolic Boundaries
Olovsson, Bild der Wissenschaft, 12-1985, 50-59
(Olovsson)
. – p.10/35
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olov-46a (fig1a)
Snow Crystals with Flat and Hyperbolic Boundaries
Hexagon, hyperbolic hexagon, star hexagon and hexagonal lattice
(Olovsson)
(snow46a,n=5)
. – p.10/35
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bh109.7-73b (fig1c)
Snow Crystals with Flat and Hyperbolic Boundaries
Bentely & Humphreys, Snow Crystals, Dover, 1962 (109.7)
. – p.11/35
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bh109.7-73b (fig1c)
Snow Crystals with Flat and Hyperbolic Boundaries
Growth lattice-sublattice in Hexagrammal vertex relation
BH 109.7
. – p.11/35
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bh109.7-73b (fig1d)
Snow Crystals with Flat and Hyperbolic Boundaries
Bentely & Humphreys, Snow Crystals, Dover, 1962 (27.3)
. – p.12/35
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bh109.7-73b (fig1d)
Snow Crystals with Flat and Hyperbolic Boundaries
Growth lattice-sublattice in Hexagrammal mid-edge relation
BH 27.3. – p.12/35
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bh167.8-84 (fig5)
Dendritic Snow Crystal with Degenerated Hyperbolic Boundaries
Bentely & Humphreys, Snow Crystals, Dover, 1962 (167.8)
. – p.13/35
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bh167.8-84 (fig5)
Dendritic Snow Crystal with Degenerated Hyperbolic Boundaries
Hyperbolic branching sites at points of the growth lattice
. – p.13/35
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rG-quadruplex
Cubic Form Lattice of RNA Guanosine QuadruplexLattice-Sublattice relation: Central channel, Guanine and Sugar-phosphate
Zimmerman, J. Mol. Biol. 106 (1976) 663-672
Cubic Form Lattice of RNA Guanosine QuadruplexBackbone subsystem: Sugar-phosphate
Zimmerman, J. Mol. Biol. 106 (1976) 663-672
Cubic Form Lattice of RNA Guanosine QuadruplexBases subsystem: Guanine
Zimmerman, J. Mol. Biol. 106 (1976) 663-672
. – p.14/35
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rG-quadruplex
Cubic Form Lattice of RNA Guanosine QuadruplexBackbone subsystem: Sugar-phosphate
Zimmerman, J. Mol. Biol. 106 (1976) 663-672
Cubic Form Lattice of RNA Guanosine QuadruplexBases subsystem: Guanine
Zimmerman, J. Mol. Biol. 106 (1976) 663-672
. – p.14/35
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rG-quadruplex
Cubic Form Lattice of RNA Guanosine QuadruplexBackbone subsystem: Sugar-phosphate
Zimmerman, J. Mol. Biol. 106 (1976) 663-672
Cubic Form Lattice of RNA Guanosine QuadruplexBases subsystem: Guanine
Zimmerman, J. Mol. Biol. 106 (1976) 663-672 . – p.14/35
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R-phycoerythrin 1-hex.
Hexameric R-phycoerythrin (Trigonal 32)
Isometric hexagonal form lattice
a
b
x
y
a = 4r°r°
x
z
4r°
Chang et al., J.Mol.Biol 262 (1996) 721-731 (PDB 1lia) . – p.15/35
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Bacteriorhodopsin sqrt(3)-hex
Bacteriorhodopsin trimer√
3-hexagonal form lattice Cubic host lattice (Lipid)
a
re
x
y
a√3r0
z
x
c = a√3
Edman et al., Nature 401 (1999) 822-826 (PDB 1qko)
a = re = 3 r0 = 1√
3c
. – p.16/35
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Penta. Lattice
Pentagonal Case
(sgk1a)
x
y1 0 0 0
0 1 0 0
0 0 1 0
0 0 0 1
-1 -1 -1 -1
Polygonal Lattice
Basis vectors:ak = a(cos kφ, sin kφ)
φ = 2π5
, k = 1, 2, 3, 4
Euler ϕ-function: ϕ(5) = 4
Note:a0 = −a1 − a2 − a3 − a4
Lattice points:P = (n1, n2, n3, n4)
Indices: n1, n2, n3, n4
(integers)
Only small indices are relevant!. – p.17/35
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Star Pentagon
Pentagonal Case
(sgk1b)
1 0 0 0
0 1 0 0
0 0 1 0
0 0 0 1
-1 -1 -1 -1
-2 0 -1 -1
1 -1 1 0
0 1 -1 1
-1 -1 0 -2
2 1 1 2
Polygrammal Scaling
Star Pentagon:Schäfli Symbol {5/2}
Scaling matrix: (planar scaling)
2̄ 1 0 1̄
0 1̄ 1 1̄
1̄ 1 1̄ 0
1̄ 0 1 2̄
Scaling factor:-1/τ2 = −0.3820...
(τ = 1+√
5
2= 1.618...)
. – p.18/35
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Linear Scaling
Pentagonal Case
(sgk1c)
x
y
A
P
Q
B
1 0 0 0
0 1 0 0
0 0 1 0
0 0 0 1
-1 -1 -1 -1
-2 0 -1 -1
1 -1 1 0
0 1 -1 1
-1 -1 0 -2
2 1 1 2
1 -1 2 -1
1 2 0 3
-3 -2 -1 -3
3 0 1 2
-2 1 -2 -1
-1 2 -1 1
-1 -1 1 -2
2 1 0 3
-3 -1 -2 -3
3 0 2 1
Pentagonal Case
(sgk1d)
τ
τ
1 x
y
A
P
Q
B
1 0 0 0
0 0 0 1
-1 -1 -1 -1
-2 0 -1 -1
1 -1 1 0
0 1 -1 1
-1 -1 0 -2
2 1 1 2
1 2 0 3
-3 -2 -1 -3
3 0 1 2
-2 1 -2 -1
-1 -1 1 -2
2 1 0 3
-3 -1 -2 -3
3 0 2 1
Linear Scaling
Scaling transformation:Yλ(x, y) = (x, λy)
Scaling matrix:
0 1 1̄ 1
1 1̄ 2 1̄
1̄ 2 1̄ 1
1 1̄ 1 0
Scaling factor:1/τ3 = 0.2361...
(τ = 1+√
5
2= 1.618...)
Linear Scaling
The linear scaling Y1/τ3
appears alongthe pentagonal edgewith the scaling ratios
τ : 1 : τ
. – p.19/35
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Linear Scaling
Pentagonal Case
(sgk1d)
τ
τ
1 x
y
A
P
Q
B
1 0 0 0
0 0 0 1
-1 -1 -1 -1
-2 0 -1 -1
1 -1 1 0
0 1 -1 1
-1 -1 0 -2
2 1 1 2
1 2 0 3
-3 -2 -1 -3
3 0 1 2
-2 1 -2 -1
-1 -1 1 -2
2 1 0 3
-3 -1 -2 -3
3 0 2 1
Linear Scaling
Scaling transformation:Yλ(x, y) = (x, λy)
Scaling matrix:
0 1 1̄ 1
1 1̄ 2 1̄
1̄ 2 1̄ 1
1 1̄ 1 0
Scaling factor:1/τ3 = 0.2361...
(τ = 1+√
5
2= 1.618...)
Linear Scaling
The linear scaling Y1/τ3
appears alongthe pentagonal edgewith the scaling ratios
τ : 1 : τ
. – p.19/35
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Cyclophylin A
Cyclophilin A - Cyclosporin A Decamer Complex
Ribbond diagram viewed down the five-fold axis
Ke et al., Current Biology Structure, 2 (1994) 33-44. – p.20/35
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Cyclo. Tau
Cyclophilin A (Decamer)
Ke and Mayrose (PDB 2rma)
τ = 1.61803... the Golden Ratio
GLY(14)
τ 1 τ
. – p.21/35
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Cyclo. Tau
Cyclophilin A (Pentamer)
Pentamer: Pentagrammal scaled form
GLY(14)
τ 1 τ
. – p.21/35
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Cyclo. Iso-decagonal
Cyclophilin: 3D Form Lattice
Isometric decagonal lattice: r0 = a = c
(cy21a)
r°
τ
τ
1 x
y
C
P
Q
x
z
4r°
2r°
. – p.22/35
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DppA Iso-pentagonal
D-aminopeptidase: 3D Form LatticeIsometric pentagonal lattice: Pentamer: τ3r0 = a = c Decamer: τ4r0 = a = c
x
yτ τ1
a
r°
Zn ion
x
z
τ4r°
τ3r°
Remaut et al., Nature Struct. Biol. 8 (2001) 674-678 (PDB 1hi9) . – p.23/35
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B-DNA
Side and Axial Views of B-DNA
S. Arnott and R. Chandrasekaran (1981)
Decagonal right-handed helix 10122 . – p.24/35
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TAu B-DNA
The Golden Ratio in B-DNA(AGTCAGTCAG) Courtesy Maria van Dongen, Nijmegen (τ = 1.61803...)
(asca6a)
Projected P-atomic positions
G10C T6S
C1S A5C
A1C
C5S
G7S
A9C
G6C
T10S
T2S
C4C
A8S
C8C
G2C
A4S
T7C
C9S
G3S
T3C
τ 1 τ
. – p.25/35
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B-DNA: Polygr. scal.
Star Decagons
Schäfli symbol { P/Q }
{ 10/2 }
λ (10/2) = 0.8506...
{ 10/3 }
λ (10/3) = 0.6180...
{ 10/4 }
λ (10/4) = 0.3249...
Polygrammal scalings with scaling factor λ(P/Q)
. – p.26/35
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B-DNA:{10/2},{10/3}
Polygrammal Scaling in B-DNA
Star decagons {10/3} and {10/2}
Backbone Region
Code-Dependent Region
Intermediate Region
. – p.27/35
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B-DNA 3D form
B-DNA (GC): 3D Form Lattice
Envelope: re Rise unit: p0 = re/2τ
(GC43f)
r e /2τp 0
r e
3D form lattice: 1
2-decagonal . – p.28/35
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evidence
Crystal’s evidence
. – p.29/35
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nt.hex.lattices
ca-Distribution of Hexagonal Crystals
Crystal Data Determinative TablesVol.2, Inorganic compounds, Donnay & Ondik, 1973
(24.000 entries)
B. Constant and P.J. Shlichta, Acta Cryst. A59 (2003) 281-282. – p.30/35
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nt.tetr.lattices
ca-Distribution of Hexagonal Crystals
√
32
1√
3√
2
√
2
√
8√
3
√
6
√
15√
22
√
8√
33
√
8√
3
. – p.30/35
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nt.tetr.lattices
ca-Distribution of Tetragonal Crystals
Crystal Data Determinative TablesVol.2, Inorganic compounds, Donnay & Ondik, 1973
(24.000 entries)
B. Constant and P.J. Shlichta, Acta Cryst. A59 (2003) 281-282 . – p.31/35
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nt.tetr.lattices
ca-Distribution of Tetragonal Crystals
12√
21√
31√
2
√
32
32√
2
√
3√
2
√
2
√
5√
22(?)
3√
2
√
6 2√
2√
107√
23
. – p.31/35
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Zn-Mg-Sn sqrt(8/3)
Z-Phase Zn6Mg3Sm:√
3
8-Hexagonal (P63/mmc)
Zone F: [211] ∼ [101̄1] Zone G: [212] ∼ [101̄2]
Singh, Abe and Tsai, Phil.Mag. Lett. 77 (1998) 95-103
Ranganathan, Singh and Tsai, Phil. Mag. Lett. 82 (2002) 13-19
. – p.32/35
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Latt.-Sublatt. sqrt(3/2)
Frank’s ’Cubic’ Hexagonal Lattice: c
a=
√
3
2
3D Hexagonal lattice projection of a 4D Cubic latticeHexagonal basis: a1, a2, a3
Sublattice basis: b1 = [0 3 0], b2 = [2̄ 1̄ 2], b3 = [2 1 1]
Metric tensors:
g(a) =
1 1̄
20
1̄
21 0
0 0 3
2
g(b) =
1 0 0
0 1 0
0 0 1
2
Transformation matrix: Sba =
0 2̄ 2
3 1̄ 1
0 2 1
Lattice-Sublattice transformation: S̃ba g(a) Sba = 9 g(b)
√
3
2-hexagonal
Sba
−→ 1√
2-tetragonal (Scaling factor 3)
F.C. Frank, Acta Cryst. 18 (1965) 862-866. – p.33/35
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Conclusions
Conclusions
The crystallographic laws are amazingly general
One learns crystallography from single molecules also
Crystallographic scaling relations between outer andinner envelope of axial bio-macromolecules
Challenging relevance of integral lattices (multimetrical)
To understand the physics of crystallographic scaling isnow a priority
. – p.34/35
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mignon
Fig. 5
4 -4 -4
4 4 -4
-4 4 -4
-4 -4 -4
4 -4 4
4 4 4
-4 4 4
-4 -4 4
4 -4 -1
4 4 -1
-4 4 -1
-4 -4 -1
4 -4 1
4 4 -1
-4 4 1
-4 -4 1
1 -1 -41 1 -4-1 1 -4
-1 -1 -4
1 -1 41 1 4-1 1 4
-1 -1 4
Kennst du das Land,
Wo Moleküle die Kristalle gleichen,
Kennst du es wohl?
Dahin! Dahin,
Geht unser Weg!
. – p.35/35