Disaccharides
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== Maltose and Cellobiose == | == Maltose and Cellobiose == | ||
| - | Maltose (α-D-glucopyranosyl (1→4) D-glucopyranose) and Cellobiose (β-D-glucopyranosyl (1→4) D-glucopyranose) are both disaccharides made of D-glucopyranose. Comparing the structures you can observe that both have a 1→4 glycosidic bond<ref>[http://en.wikipedia.org/wiki/Glycosidic_bond Glycosidic bond]</ref>. C-1 (orange) of one glucose unit is bonded to the oxygen of C-4 of the second unit. The difference between the two is that maltose is α(1→4) and cellobiose is β(1→4). As you study the two structures notice that with cellobiose the second glucopyranose unit is rotated 180°, so that the oxygen bonds of both C-1 (β configuration) and C-4 of the second glucopyranose unit are projecting up so that oxygen has its normal angular geometry. In order to see the second glucopyranose in its normal position, rotate cellobiose 180° about the x axis so that C-6 is in the back of the ring and projecting upward | + | Maltose (α-D-glucopyranosyl (1→4) D-glucopyranose) and Cellobiose (β-D-glucopyranosyl (1→4) D-glucopyranose) are both disaccharides made of D-glucopyranose. Comparing the structures you can observe that both have a 1→4 glycosidic bond<ref>[http://en.wikipedia.org/wiki/Glycosidic_bond Glycosidic bond]</ref>. C-1 (orange) of one glucose unit is bonded to the oxygen of C-4 of the second unit. The difference between the two is that maltose is α(1→4) and cellobiose is β(1→4). As you study the two structures notice that with cellobiose the second glucopyranose unit is rotated 180°, so that the oxygen bonds of both C-1 (β configuration) and C-4 of the second glucopyranose unit are projecting up so that oxygen has its normal angular geometry. In order to see the second glucopyranose in its normal position, rotate cellobiose 180° about the x axis so that C-6 is in the back of the ring and projecting upward. Both structures show the anomeric carbon (green) of the second glucose unit as the β anomer, but in an aqueous solution that designation would not be significant because there would be an equilibrium mixture of the α and β anomers and the open-chain structure. The open-chain structure in an aqueous solution provides an aldehyde group which can be oxidized, so maltose and cellobiose are reducing sugars<ref>[http://en.wikipedia.org/wiki/Reducing_sugar Reducing sugar]</ref>. Also, notice the sharp bend in the maltose at the glycosidic bond. Most text books do not represent the structure of maltose in a way that shows this bend. View this <scene name='Disaccharides/Maltose2/2' target='0'>bend</scene> or <scene name='Disaccharides/Cellobiose2/1' target='1'>lack of bend</scene> in spacefill. |
| - | <Structure load='Maltose.pdb' size='400' frame='true' align='left' caption='' scene='Disaccharides/Maltose/ | + | <Structure load='Maltose.pdb' size='400' frame='true' align='left' caption='' scene='Disaccharides/Maltose/2' /> |
| - | <Structure load='Cellobiose.pdb' size='400' frame='true' align='left' caption='' scene='Disaccharides/Cellobiose/ | + | <Structure load='Cellobiose.pdb' size='400' frame='true' align='left' caption='' scene='Disaccharides/Cellobiose/2' /> |
Revision as of 19:51, 8 November 2011
The objective of this article is to illustrate and visualize the structures and concepts of disaccharides[1] that are difficult to visualize and illustrate by viewing two dimensional structures in textbooks.
Maltose and Cellobiose
Maltose (α-D-glucopyranosyl (1→4) D-glucopyranose) and Cellobiose (β-D-glucopyranosyl (1→4) D-glucopyranose) are both disaccharides made of D-glucopyranose. Comparing the structures you can observe that both have a 1→4 glycosidic bond[2]. C-1 (orange) of one glucose unit is bonded to the oxygen of C-4 of the second unit. The difference between the two is that maltose is α(1→4) and cellobiose is β(1→4). As you study the two structures notice that with cellobiose the second glucopyranose unit is rotated 180°, so that the oxygen bonds of both C-1 (β configuration) and C-4 of the second glucopyranose unit are projecting up so that oxygen has its normal angular geometry. In order to see the second glucopyranose in its normal position, rotate cellobiose 180° about the x axis so that C-6 is in the back of the ring and projecting upward. Both structures show the anomeric carbon (green) of the second glucose unit as the β anomer, but in an aqueous solution that designation would not be significant because there would be an equilibrium mixture of the α and β anomers and the open-chain structure. The open-chain structure in an aqueous solution provides an aldehyde group which can be oxidized, so maltose and cellobiose are reducing sugars[3]. Also, notice the sharp bend in the maltose at the glycosidic bond. Most text books do not represent the structure of maltose in a way that shows this bend. View this or in spacefill.
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Karl Oberholser, Alexander Berchansky, Jaime Prilusky, Karsten Theis
