Syn and anti nucleosides
From Proteopedia
(Difference between revisions)
(of course C and T take part in Z-DNA, although only in the anti- conformation) |
m (Changed "configuration" to "conformation" at several instances) |
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== Purine Nucleosides == | == Purine Nucleosides == | ||
| - | Adenosine (<scene name='Syn_and_anti_nucleosides/First_view/1'>Reset Initial scene</scene>) is composed of an adenine bonded to a furanose by a <scene name='Syn_and_anti_nucleosides/Glycosidic_bond/1'>β glycosidic bond</scene> (colored green). Observe that the adenine ring is nearly perpendicular to the furanose ring, but projecting away from the furanose (anti conformation). Without hinderance from groups on either ring the adenine ring can rotate about the glycosidic bond, and form the <scene name='Syn_and_anti_nucleosides/Syn-conformation/1'>syn conformation</scene>. The two common purines, adenine and guanine, can rotate between the anti and syn conformations, but the anti | + | Adenosine (<scene name='Syn_and_anti_nucleosides/First_view/1'>Reset Initial scene</scene>) is composed of an adenine bonded to a furanose by a <scene name='Syn_and_anti_nucleosides/Glycosidic_bond/1'>β glycosidic bond</scene> (colored green). Observe that the adenine ring is nearly perpendicular to the furanose ring, but projecting away from the furanose (anti conformation). Without hinderance from groups on either ring the adenine ring can rotate about the glycosidic bond, and form the <scene name='Syn_and_anti_nucleosides/Syn-conformation/1'>syn conformation</scene>. The two common purines, adenine and guanine, can rotate between the anti and syn conformations, but the anti conformation is favored. Compare the contact present between the two rings in these two spacfilling representations, <scene name='Syn_and_anti_nucleosides/Anti-conformation2/1'>anti conformation</scene> and <scene name='Syn_and_anti_nucleosides/Syn-conformation2/1'>syn conformation</scene>. Even though the anti conformation is favored with the purines the syn conformation can be formed and actually has a role in the formation of the [[Z-DNA]], a conformation of DNA double helix. |
== Pyrimidine Nucleosides == | == Pyrimidine Nucleosides == | ||
| - | <scene name='Syn_and_anti_nucleosides/Anti-uridine/1'>View</scene> of uridine in the anti | + | <scene name='Syn_and_anti_nucleosides/Anti-uridine/1'>View</scene> of uridine in the anti conformation, the oxygen on <font color=orange>C-2</font> of uridine is projecting away from the furanose ring. <scene name='Syn_and_anti_nucleosides/Syn-cytidine/1'>View</scene> of cytidine in the syn conformation, the oxygen on <font color=orange>C-2</font> is projecting toward the furanose ring. This oxygen at the <font color=orange>C-2</font> position produces significant hinderance to the rotation of the pyrimidine about the glycosidic bond as shown in this <scene name='Syn_and_anti_nucleosides/Syn-cytidine2/1'>scene</scene>. The oxygen doubled bonded to the <font color=orange>C-2</font> invades the space of the hydrogen at C-2' and to a lesser extent the oxygen of the furanose ring. Since both pyrimidines found in DNA have an oxygen at the C-2 position, nucleosides and nucleotides of these pyrimidines only adopt the anti conformation and they do so even in Z-DNA. |
== 3D Images of Nucleotides == | == 3D Images of Nucleotides == | ||
Current revision
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Proteopedia Page Contributors and Editors (what is this?)
Karl Oberholser, Angel Herraez, David Canner, Alexander Berchansky, Norbert Sträter
