User:Robert Dutnall/Sandbox 1 sheets

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Revision as of 22:08, 28 August 2011

1 Biochemistry Tutorial #2 - Secondary Structure
2 β-strands and β-sheets
- 2.1 Parallel β-sheet
- 2.2 Anti-Parallel β-sheet
3

Biochemistry Tutorial #2 - Secondary Structure

Part Two

β-strands and β-sheets

The second major secondary structure element is the β-sheet. β-sheets are composed of two or more segments of polypeptide mainchain in β-strand conformation. In a β-strand, the polypeptide mainchain is in a mostly extended conformation. As their name implies, β-sheets are relatively flat, planar-like structures made up of β-strands arranged side-by-side. They come in three flavors: parallel, anti-parallel and mixed, which differ in terms of the orientation of each component strand (with respect to the direction of the mainchain from N-terminus to C-terminus).

Note that the mainchain of a β-strand is not perfectly fully extended (Φ ≠ φ ≠ 180^o) and that the mainchain actually slowly twists (this is more obvious if you look at a long segment of β-strand). Thus β-sheets are not completely flat and also exhibit some twisting (this is also more obvious if you look at sheets made of many β-strands).

Parallel β-sheet

Parallel β-sheets are composed of β-strands that all point in the same direction. Each β-strand has mainchain dihedral angles as follows: Φ ~ -120^o, φ ~ +105^o.

The sheet shown below is composed of three strands in parallel orientation. All the atoms are shown (C = green; N = blue; O = red; S = yellow; H = white).

to show only the polypeptide mainchain (NH, Cα, and C=O).

Identify the N- and C-termini of each strand.

As the structure rotates you should be able to see the extended nature of each strand and the parallel orientation of the three strands.

to stop the structure spinning and view the sheet from roughly perpendicular to its flat plane, with each strand running left-to-right (N- to C-terminus).

to stop the structure spinning and view the sheet from roughly edge-on to its flat plane.

Look at the structure carefully and identify the mainchain NH and C=O groups. What is the orientation of these groups with respect to the long axis of each strand? What the orientation of these groups with respect to the flat plane of the sheet?

The hydrogen bonds connect backbone NH groups and C=O groups. The N-H group is the hydrogen bond donor, the oxygen in the C=O group is the acceptor (N-H--->O=C). Each hydrogen bond is approximately 3.0 Angstroms (0.3 nm) in length (measured between the N and the O).

You should be able to see that the mainchain NH and C=O groups are involved in hydrogen bonds. In each strand the mainchain NH and C=O groups point to opposite sides of the mainchain (because of the almost fully extended conformation). The strands line up in the sheet so that these NH and C=O groups are parallel to plane of the sheet. This means that hydrogen bonds can be made between the strands of the sheet.

You should also notice that all of the NH and C=O groups that lie between strands are involved in hydrogen bonds. Only the groups on the edges of the sheet do not have hydrogen bond partners. However, as with helix capping, if this sheet were part of a larger protein, other residues would supply groups to hydrogen bond to most if not all of these.

You are looking roughly edge-on to the flat plane of the sheet and the atoms of each amino side chain have been colored light blue to show them more clearly.

What is the general orientation of the side chains with respect to each strand and the sheet? You should observe that the side chains are approximately perpendicular to the flat plane of the sheet. Along each strand, the side chains alternate direction. You can see this more clearly if we color the side chains in one strand alternately. to freeze the view and color the side chains along one strand blue-purple-blue-purple...etc.

If we apply this to all the strands () you can see that all the sidechains above the plane of the sheet are purple, and all those below are blue.

Anti-Parallel β-sheet

Anti-parallel β-sheets are composed of β-strands that alternate in direction. Each β-strand has mainchain dihedral angles as follows: Φ ~ -120^o, φ ~ +105^o.

The sheet shown below is composed of three strands in anti-parallel orientation. All the atoms are shown (C = green; N = blue; O = red; S = yellow; H = white).

to show only the polypeptide mainchain (NH, Cα, and C=O).

Identify the N- and C-termini of each strand.

As the structure rotates you should be able to see the extended nature of each strand and the parallel orientation of the three strands.

to stop the structure spinning and view the sheet from roughly perpendicular to its flat plane, with each strand running left-to-right (N- to C-terminus).

to stop the structure spinning and view the sheet from roughly edge-on to its flat plane.

You are looking roughly edge-on to the flat plane of the sheet and the atoms of each amino side chain have been colored light blue to show them more clearly.

If we apply this to all the strands () you can see that all the sidechains above the plane of the sheet are purple, and all those below are blue.

Click here to go on to back to the first part of this tutorial.

Proteopedia Page Contributors and Editors (what is this?)

Robert Dutnall

Retrieved from "http://52.214.119.220/wiki/index.php/User:Robert_Dutnall/Sandbox_1_sheets"

@@ Line 11: / Line 11: @@
 ==Parallel β-sheet==
-Parallel β-sheets are composed of β-strand that all point in the same direction. Each β-strand has mainchain dihedral angles as follows: Φ ~ -120<sup>o</sup>, φ ~ +105<sup>o</sup>.
+Parallel β-sheets are composed of β-strands that all point in the same direction. Each β-strand has mainchain dihedral angles as follows: Φ ~ -120<sup>o</sup>, φ ~ +105<sup>o</sup>.
-The sheet shown below is composed of three strands in parallel orientation.
+The sheet shown below is composed of three strands in parallel orientation. All the atoms are shown (C = green; N = blue; O = red; S = yellow; H = white).
-<Structure load='Tut_parallel_bsheet.pdb' size='500' frame='true' align='left' caption='' scene='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_load/1'/>
+<Structure load='Tut_parallel_bsheet.pdb' size='500' frame='true' align='left' caption='' scene='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_load/2'/>
-All the atoms are shown in this initial orientation (C = green; N = blue; O = red; S = yellow; H = white).
+<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain/2'>Click here</scene> to show only the polypeptide mainchain (NH, Cα, and C=O).
-<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain/1'>Click here</scene> to show only the polypeptide mainchain (NH, Cα, and C=O).
+Identify the N- and C-termini of each strand. <scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels/6'>Click here to see if you were correct.</scene>
-Identify the N- and C-termini of each strand. <scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels/5'>Click here to see if you were correct.</scene>
 As the structure rotates you should be able to see the extended nature of each strand and the parallel orientation of the three strands.
-<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_face/1'>Click here</scene> to stop the structure spinning and view the sheet from roughly perpendicular to its flat plane.
+<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_face/2'>Click here</scene> to stop the structure spinning and view the sheet from roughly perpendicular to its flat plane, with each strand running left-to-right (N- to C-terminus).
-<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_side/1'>Click here</scene> to stop the structure spinning and view the sheet from roughly edge-on to its flat plane.
-<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels/5'>Click here to start the structure spinning again.</scene> Look at the structure carefully and identify the mainchain NH and C=O groups. What is the orientation of these groups with respect to the long axis of each strand? What the orientation of these groups with respect to the flat plane of the sheet?
+<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_side/2'>Click here</scene> to stop the structure spinning and view the sheet from roughly edge-on to its flat plane.
-<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_hb/4'>Click here to add hydrogen bonds for the mainchain (dashed lines).</scene> The hydrogen bonds connect backbone NH groups and C=O groups. The N-H group is the hydrogen bond donor, the oxygen in the C=O group is the acceptor (N-H--->O=C). Each hydrogen bond is approximately 3.0 Angstroms (0.3 nm) in length (measured between the N and the O).
+<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels/6'>Click here to start the structure spinning again.</scene> Look at the structure carefully and identify the mainchain NH and C=O groups. What is the orientation of these groups with respect to the long axis of each strand? What the orientation of these groups with respect to the flat plane of the sheet?
-You should be able to see that the mainchain NH and C=O groups are involved in hydrogen bonds. In each strand the mainchain NH and C=O groups point to opposite sides of the mainchain (because of the almost fully extended conformation). The strands line up in the sheet so that these NH and C=O groups are parallel to plane of the sheet. This means that hydrogen bonds can be made between the strands of the sheet. <scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_hb_z/4'>Click here to zoom in to show some of the hydrogen bonds more clearly.</scene>
+<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_hb/5'>Click here to add hydrogen bonds for the mainchain (dashed lines).</scene> The hydrogen bonds connect backbone NH groups and C=O groups. The N-H group is the hydrogen bond donor, the oxygen in the C=O group is the acceptor (N-H--->O=C). Each hydrogen bond is approximately 3.0 Angstroms (0.3 nm) in length (measured between the N and the O).
-<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_hb/4'>Click here to zoom out again.</scene>
+You should be able to see that the mainchain NH and C=O groups are involved in hydrogen bonds. In each strand the mainchain NH and C=O groups point to opposite sides of the mainchain (because of the almost fully extended conformation). The strands line up in the sheet so that these NH and C=O groups are parallel to plane of the sheet. This means that hydrogen bonds can be made between the strands of the sheet. <scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_hb_z/5'>Click here to zoom in to show some of the hydrogen bonds more clearly.</scene>
-You should also notice that all of the NH and C=O groups that lie between strands are involved in hydrogen bonds. Only the groups on the edges of the sheet do not have hydrogen bond partners. However, as with helix capping, if this sheet were part of a larger protein, other residues would supply groups to hydrogen bond to most if not all of these.
+<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_hb/5'>Click here to zoom out again.</scene> You should also notice that all of the NH and C=O groups that lie between strands are involved in hydrogen bonds. Only the groups on the edges of the sheet do not have hydrogen bond partners. However, as with helix capping, if this sheet were part of a larger protein, other residues would supply groups to hydrogen bond to most if not all of these.
-<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_sidechains/1'>Click here to show the side chains again.</scene> The atoms of each amino side chain have been colored light blue to show them more clearly.
+<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_sidechains/2'>Click here to show the side chains again.</scene> You are looking roughly edge-on to the flat plane of the sheet and the atoms of each amino side chain have been colored light blue to show them more clearly.
-What is the general orientation of the side chains with respect to each strand and the sheet? You should observe that the side chains are approximately perpendicular to the flat plane of the sheet. Along each strand, the side chains alternate direction. You can see this more clearly if we color the side chains in one strand alternately. <scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_strand_alt/1'>Click here</scene> to color the side chains along one strand blue-purple-blue-purple...etc. If we apply this to all the sheets (<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_sidechains_alt/1'>click here</scene>) you can see that all the amino acids on one face of the sheet are blue, and on the other are purple.
+What is the general orientation of the side chains with respect to each strand and the sheet? You should observe that the side chains are approximately perpendicular to the flat plane of the sheet. Along each strand, the side chains alternate direction. You can see this more clearly if we color the side chains in one strand alternately. <scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_strand_alt/3'>Click here</scene> to freeze the view and color the side chains along one strand blue-purple-blue-purple...etc.
+If we apply this to all the strands (<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_sidechains_alt/2'>click here</scene>) you can see that all the sidechains above the plane of the sheet are purple, and all those below are blue.
-==The 3<sub>10</sub>-helix==
-<sub>10</sub>-helices are also found in proteins but are less common than α-helices. They are characterized by the following helix parameters:
+==Anti-Parallel β-sheet==
-::Dihedral angles: Φ ~ -49<sup>o</sup>, φ ~ -26<sup>o</sup>
-::Repeat (number of residues per turn) = 3.0
+Anti-parallel β-sheets are composed of β-strands that alternate in direction. Each β-strand has mainchain dihedral angles as follows: Φ ~ -120<sup>o</sup>, φ ~ +105<sup>o</sup>.
-::Rise (translation along axis per amino acid residue) = 2.0 Angstroms (0.2 nm)
-::Twist (rotation around axis per amino acid residue) = 120<sup>o</sup> (= 360<sup>o</sup>/repeat)
+The sheet shown below is composed of three strands in anti-parallel orientation. All the atoms are shown (C = green; N = blue; O = red; S = yellow; H = white).
-::Pitch (translation along axis per turn) = 6.0 Angstroms (= 0.6 nm = Repeat x Rise)
+<Structure load='Tut_parallel_bsheet.pdb' size='500' frame='true' align='left' caption='' scene='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_load/2'/>
+<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain/2'>Click here</scene> to show only the polypeptide mainchain (NH, Cα, and C=O).
+Identify the N- and C-termini of each strand. <scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels/6'>Click here to see if you were correct.</scene>
+As the structure rotates you should be able to see the extended nature of each strand and the parallel orientation of the three strands.
-The helix shown below is a 19 amino acid chain in 3<sub>10</sub>-helical conformation.
+<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_face/2'>Click here</scene> to stop the structure spinning and view the sheet from roughly perpendicular to its flat plane, with each strand running left-to-right (N- to C-terminus).
-<Structure load='Tut_3-10_helix.pdb' size='500' frame='true' align='left' caption='' scene='User:Robert_Dutnall/Sandbox_1_alpha_helix/310_helix_load/4'/>
-All the atoms are shown in this initial orientation (C = green; N = blue; O = red; S = yellow; H = white). The helix axis runs vertically, approximately parallel to the plane of the screen.
+<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_side/2'>Click here</scene> to stop the structure spinning and view the sheet from roughly edge-on to its flat plane.
-<scene name='User:Robert_Dutnall/Sandbox_1_alpha_helix/310_helix_mainchain/2'>Click here</scene> to show only the polypeptide mainchain (NH, Cα, and C=O). The N- and C-termini are labeled.
+<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels/6'>Click here to start the structure spinning again.</scene> Look at the structure carefully and identify the mainchain NH and C=O groups. What is the orientation of these groups with respect to the long axis of each strand? What the orientation of these groups with respect to the flat plane of the sheet?
-<scene name='User:Robert_Dutnall/Sandbox_1_alpha_helix/310_helix_mainchain_ribbon/2'>Click here to add a ribbon that will help show the path of the mainchain. </scene> You should be able to see that just like the α-helix, it is helical with a right-handed twist, and again, all the mainchain NH groups point toward the N-terminus, and all the mainchain C=O groups point toward the C-terminus.
+<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_hb/5'>Click here to add hydrogen bonds for the mainchain (dashed lines).</scene> The hydrogen bonds connect backbone NH groups and C=O groups. The N-H group is the hydrogen bond donor, the oxygen in the C=O group is the acceptor (N-H--->O=C). Each hydrogen bond is approximately 3.0 Angstroms (0.3 nm) in length (measured between the N and the O).
-The difference between an α-helix and a 3<sub>10</sub>-helix lies in the helix parameters. A 3<sub>10</sub>-helix is more tightly twisted so that the mainchain completes one turn every 3 amino acids (instead of 3.6 for the α-helix). This also results in a larger rise and pitch so that the 3<sub>10</sub>-helix is longer than an α-helix (of the same number of residues).
+You should be able to see that the mainchain NH and C=O groups are involved in hydrogen bonds. In each strand the mainchain NH and C=O groups point to opposite sides of the mainchain (because of the almost fully extended conformation). The strands line up in the sheet so that these NH and C=O groups are parallel to plane of the sheet. This means that hydrogen bonds can be made between the strands of the sheet. <scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_hb_z/5'>Click here to zoom in to show some of the hydrogen bonds more clearly.</scene>
-<scene name='User:Robert_Dutnall/Sandbox_1_alpha_helix/310_helix_mainchain_axis/1'>Click here </scene>to zoom in and look down the helix axis from the N-terminal end. You'll be able to see the triangular shape of the mainchain.
+<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_mainchain_labels_hb/5'>Click here to zoom out again.</scene> You should also notice that all of the NH and C=O groups that lie between strands are involved in hydrogen bonds. Only the groups on the edges of the sheet do not have hydrogen bond partners. However, as with helix capping, if this sheet were part of a larger protein, other residues would supply groups to hydrogen bond to most if not all of these.
-<scene name='User:Robert_Dutnall/Sandbox_1_alpha_helix/310_helix_mainchain_hbonds/1'>Click here to zoom out again and display hydrogen bonds for the mainchain.</scene> Once again, all of the mainchain NH and C=O groups are involved in hydrogen bonds. However, now the hydrogen bonds connect amino acids that are spaced 3 residues apart in the primary sequence. The NH group is from amino acid X and the O is from amino acid X-3 (where X is the number of the amino acid in the sequence). <scene name='User:Robert_Dutnall/Sandbox_1_alpha_helix/310_helix_mainchain_hbonds/2'>Click here</scene> to zoom in and you should be able to see this more clearly.
+<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_sidechains/2'>Click here to show the side chains again.</scene> You are looking roughly edge-on to the flat plane of the sheet and the atoms of each amino side chain have been colored light blue to show them more clearly.
-<scene name='User:Robert_Dutnall/Sandbox_1_alpha_helix/310_helix_sidechains/1'>Click here to zoom out and show the side chains again.</scene> The atoms of each amino side chain have been colored light blue to show them more clearly. <scene name='User:Robert_Dutnall/Sandbox_1_alpha_helix/310_helix_sidechains_axis/2'>Click here to change the view to look down the helix axis.</scene>
+What is the general orientation of the side chains with respect to each strand and the sheet? You should observe that the side chains are approximately perpendicular to the flat plane of the sheet. Along each strand, the side chains alternate direction. You can see this more clearly if we color the side chains in one strand alternately. <scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_strand_alt/3'>Click here</scene> to freeze the view and color the side chains along one strand blue-purple-blue-purple...etc.
-As for the α-helix, each side chain points away from the helix axis, and points down toward the N-terminus of the helix. However, because the 3<sub>10</sub>-helix repeat parameter is an integer (= 3.0), the side chains are spaced 120<sup>o</sup> apart and form 3 distinct sides to the helix. You'll see this more clearly if the side chains are colored in groups to show this (residues 1,4,7,10 etc are blue; residues 2,5,8,11 etc are purple; residues 3,6,9,12 etc are yellow): <scene name='User:Robert_Dutnall/Sandbox_1_alpha_helix/310_helix_sidechains_tricolor/1'>click here to look from the side</scene> or <scene name='User:Robert_Dutnall/Sandbox_1_alpha_helix/310_helix_sidechains_tricol_ax/1'>click here to view down the helix axis</scene>.
+If we apply this to all the strands (<scene name='User:Robert_Dutnall/Sandbox_1_sheets/Parallel_sidechains_alt/2'>click here</scene>) you can see that all the sidechains above the plane of the sheet are purple, and all those below are blue.

User:Robert Dutnall/Sandbox 1 sheets

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Revision as of 22:08, 28 August 2011

Contents

Biochemistry Tutorial #2 - Secondary Structure

β-strands and β-sheets

Parallel β-sheet

Anti-Parallel β-sheet

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