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A-RNA tour

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 == Take the Tour ==
-The tour starts with the <scene name='72/725869/A-rna_overview/1'>Default</scene> view. Now look at this <scene name='72/725442/Space_filling_view/2'>space filling view</scene>.The backbone is yellow and the bases are magenta. Note that the major groove (in the middle, when you have just clicked the button) is wide and easily accessible.
+The tour starts with the <scene name='72/725869/A-rna_overview/1'>Default</scene> view. Now look at this <scene name='72/725869/Rna_space_filling_view/2'>space filling view</scene>.The backbone is yellow and the bases are magenta. Note that the major groove (at the top, when you have just clicked the button) is very deep.
-Now change the display to make it show the <scene name='72/725442/Space_filling_bbone/2'>sugar-phosphate backbone as pseudo-bonds</scene>  connecting the phosphate atoms.  Now the bases are easier to see. Notice how they are stacked upon each other and are nearly perpendicular to the axis of the double helix. Note also that the backbone forms a smooth, continuous curve.
+Now change the display to make the show the <scene name='72/725869/Rna_space_filling_bbone/1'>sugar-phosphate backbone as pseudo-bonds</scene> connecting the phosphate atoms.  Now the bases are easier to see. Notice how they are stacked upon each other but not perpendicular to the axis of the double helix. They are also displaced to the side of the axis. The result is a wide, short helix. Note also that the backbone forms a smooth, continuous curve.
-You can <scene name='72/725442/Zoom_pairs/1'>look at just four of the base pairs.</scene>.You are looking into the major groove and the colors of the base pairs alternate. You can also <scene name='72/725442/Zoom_pairs_only/1'>looks at just the bases</scene>.
+You can <scene name='72/725442/Zoom_pairs/1'>look at just four of the base pairs</scene>.You are looking into the major groove and the colors of the base pairs alternate. You can also <scene name='72/725442/Zoom_pairs_only/1'>looks at just the bases</scene>.
 Each base pair stacks on the next similarly, as shown from <scene name='72/725442/Zoom_pairs_top/1'>this top view</scene>. This is the <scene name='72/725442/Zoom_pairs_only_top/1'>same top view of just the bases</scene>.  A-form DNA also stacks in this way, but compare this with Z-DNA, which behaves much differently.

Revision as of 14:46, 21 February 2016

A-form RNA

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A-RNA

Show:Asymmetric Unit Biological Assembly

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Structural highlights

Most RNA and RNA-DNA duplex in this form
Shorter, wider helix than B.
Deep, narrow major groove not easily accessible to proteins
Wide, shallow minor groove accessible to proteins, but lower information content than major groove.
Favored conformation at low water concentrations
Base pairs tilted to helix axis and displaced from axis
Sugar pucker C3'-endo (in RNA 2'-OH inhibits C2'-endo conformation)

Take the Tour

The tour starts with the view. Now look at this .The backbone is yellow and the bases are magenta. Note that the major groove (at the top, when you have just clicked the button) is very deep.

Now change the display to make the show the connecting the phosphate atoms. Now the bases are easier to see. Notice how they are stacked upon each other but not perpendicular to the axis of the double helix. They are also displaced to the side of the axis. The result is a wide, short helix. Note also that the backbone forms a smooth, continuous curve.

You can .You are looking into the major groove and the colors of the base pairs alternate. You can also .

Each base pair stacks on the next similarly, as shown from . This is the . A-form DNA also stacks in this way, but compare this with Z-DNA, which behaves much differently.

DNA is usually found in the B form under physiological conditions. The B-form conformation is stabilized by water molecules bound to the minor groove. You can see them as red dots . Sometimes kinks are found in the B helix at transcriptional control regions. These kinks can either be intrinsic to the DNA sequence or caused by transcription factor binding.

You can compare it with the DNA forms by looking at this 3D red-blue stern picture of A, B, and Z DNA

References

R. E. Dickerson, H. R. Drew, B. N. Conner, R. M. Wing, A. V. Fratini & M. L. Kopka (1982) The anatomy of A-, B-, and Z-DNA. Science 216: 475-485 ^[1] JSmol in Proteopedia ^[2] or to the article describing Jmol ^[3] to the rescue.

Proteopedia Page Contributors and Editors (what is this?)

James Nolan, Michal Harel

Retrieved from "http://52.214.119.220/wiki/index.php/A-RNA_tour"

A-RNA tour

From Proteopedia

Revision as of 14:46, 21 February 2016

A-form RNA

Structural highlights

Take the Tour

References

Proteopedia Page Contributors and Editors (what is this?)

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