CAZypedia needs your help!
We have many unassigned pages in need of Authors and Responsible Curators. See a page that's out-of-date and just needs a touch-up? - You are also welcome to become a CAZypedian. Here's how.
Scientists at all career stages, including students, are welcome to contribute.
Learn more about CAZypedia's misson here and in this article.
Totally new to the CAZy classification? Read this first.

Difference between revisions of "Anomeric centre (alpha and beta)"

From CAZypedia
Jump to navigation Jump to search
(Uploaded arabinose figure under new filename to force new image loading)
 
(6 intermediate revisions by 2 users not shown)
Line 8: Line 8:
 
The configuration at the anomeric centre (that derived from the carbonyl carbon) is denoted alpha- (α-) or beta- (β-) by reference to the stereocentre that determines the absolute configuration. In a Fischer projection, if the substituent off the anomeric centre is on the same side as the oxygen of the configurational (D- or L-) carbon, then it is the α--anomer. If it is directed in the opposite direction it is the β-anomer.
 
The configuration at the anomeric centre (that derived from the carbonyl carbon) is denoted alpha- (α-) or beta- (β-) by reference to the stereocentre that determines the absolute configuration. In a Fischer projection, if the substituent off the anomeric centre is on the same side as the oxygen of the configurational (D- or L-) carbon, then it is the α--anomer. If it is directed in the opposite direction it is the β-anomer.
  
[[Image:alpha&beta_arabinose.png|center|900px]]
+
[[File:Alphabeta arabinose.png|center|700px]]
 
<center>'''Example 1. Fischer projections and Haworth conformational projections of L-arabinose.</center>
 
<center>'''Example 1. Fischer projections and Haworth conformational projections of L-arabinose.</center>
 +
<br>
  
[[Image:alpha&beta_fructose.png|center|900px]]
+
[[File:alpha&beta_fructose.png|center|1000px]]
 
<center>'''Example 2. Fischer projections and Haworth conformational projections of D-fructose.'''</center>
 
<center>'''Example 2. Fischer projections and Haworth conformational projections of D-fructose.'''</center>
  
 
In the case of D-hexopyranoses drawn in the 'usual' Haworth projection, the &alpha;-D-anomer is the isomer with the anomeric substituent on the opposite face to the C5 (hydroxymethyl) substitutent, ie directed ‘down’; the &beta;-D-anomer is that with the anomeric substituent being on the same face as the C5 hydroxymethyl substitutent, ie directed up. For L-hexoses the &alpha;-L-anomer has the anomeric group pointing up; the &beta;-L-anomer has this group pointing down.
 
In the case of D-hexopyranoses drawn in the 'usual' Haworth projection, the &alpha;-D-anomer is the isomer with the anomeric substituent on the opposite face to the C5 (hydroxymethyl) substitutent, ie directed ‘down’; the &beta;-D-anomer is that with the anomeric substituent being on the same face as the C5 hydroxymethyl substitutent, ie directed up. For L-hexoses the &alpha;-L-anomer has the anomeric group pointing up; the &beta;-L-anomer has this group pointing down.
  
[[Image:alpha&beta_glucose.png|center|750px]]
+
[[File:alpha&beta_glucose.png|center|700px]]
 
<center>'''Example 3. Fischer projections and Haworth conformational projections of D-glucose.'''</center>
 
<center>'''Example 3. Fischer projections and Haworth conformational projections of D-glucose.'''</center>
  
 
==References==
 
==References==
 
<biblio>
 
<biblio>
#StickWilliams isbn=978-0-240-52118-3
+
#StickWilliams2009 isbn=9780240521183
 
</biblio>
 
</biblio>
 
[[Category:Definitions and explanations]]
 
[[Category:Definitions and explanations]]

Latest revision as of 10:19, 7 November 2014

Approve icon-50px.png

This page has been approved by the Responsible Curator as essentially complete. CAZypedia is a living document, so further improvement of this page is still possible. If you would like to suggest an addition or correction, please contact the page's Responsible Curator directly by e-mail.


The anomeric centre of a sugar is a stereocentre created from the intramolecular formation of an acetal (or ketal) of a sugar hydroxyl group and an aldehyde (or ketone) group. The two stereoisomers formed from the two possible stereochemistries at the anomeric centre are called anomers. They are diastereoisomers of one another.

The configuration at the anomeric centre (that derived from the carbonyl carbon) is denoted alpha- (α-) or beta- (β-) by reference to the stereocentre that determines the absolute configuration. In a Fischer projection, if the substituent off the anomeric centre is on the same side as the oxygen of the configurational (D- or L-) carbon, then it is the α--anomer. If it is directed in the opposite direction it is the β-anomer.

Alphabeta arabinose.png
Example 1. Fischer projections and Haworth conformational projections of L-arabinose.


Alpha&beta fructose.png
Example 2. Fischer projections and Haworth conformational projections of D-fructose.

In the case of D-hexopyranoses drawn in the 'usual' Haworth projection, the α-D-anomer is the isomer with the anomeric substituent on the opposite face to the C5 (hydroxymethyl) substitutent, ie directed ‘down’; the β-D-anomer is that with the anomeric substituent being on the same face as the C5 hydroxymethyl substitutent, ie directed up. For L-hexoses the α-L-anomer has the anomeric group pointing up; the β-L-anomer has this group pointing down.

Alpha&beta glucose.png
Example 3. Fischer projections and Haworth conformational projections of D-glucose.

References

  1. [StickWilliams2009]