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Sugar Chemistry

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Sugar Chemistry & Glycobiology In Solomons, ch.22 (pp 1073-1084, 1095-1100) Sugars are poly-hydroxy aldehydes or ketones Examples of simple sugars that may have ... – PowerPoint PPT presentation

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Title: Sugar Chemistry


1
Sugar Chemistry Glycobiology
  • In Solomons, ch.22 (pp 1073-1084, 1095-1100)
  • Sugars are poly-hydroxy aldehydes or ketones
  • Examples of simple sugars that may have existed
    in the pre-biotic world

2
  • Most sugars, e.g. glyceraldehyde, are chiral sp3
    hybridized C with 4 different substituents
  • The last structure is the Fischer projection
  • CHO at the top
  • Carbon chain runs downward
  • Bonds that are vertical point down from chiral
    centre
  • Bonds that are horizontal point up
  • H is not shown line to LHS is not a methyl group

3
  • In (R) glyceraldehyde, H is to the left, OH to
    the right ? D configuration if OH is on the
    left, then it is L
  • D/L does NOT correlate with R/S
  • Most naturally occurring sugars are D, e.g.
    D-glucose
  • (R)-glyceraldehyde is optically active rotates
    plane polarized light (def. of chirality)
  • (R)-D-glyceraldehyde rotates clockwise, ? it is
    the () enantiomer, and also d-, dextro-rotatory
    (rotates to the right-dexter)
  • ? (R)-D-()-d-glyceraldehyde
  • its enantiomer is (S)-L-(-)-l-glyderald
    ehyde
  • ()/d (-)/l do NOT correlate with D/L or R/S

4
  • Glyceraldehyde is an aldo-triose (3 carbons)
  • Tetroses ? 4 Cs have 2 chiral centres
  • 4 stereoisomers
  • D/L erythrose pair of enantiomers
  • D/L threose - pair of enantiomers
  • Erythrose threose are diastereomers
    stereoisomers that are NOT enantiomers
  • D-threose D-erythrose
  • D refers to the chiral centre furthest down the
    chain (penultimate carbon)
  • Both are (-) even though glyceraldehyde is () ?
    they differ in stereochemistry at top chiral
    centre
  • Pentoses D-ribose in DNA
  • Hexoses D-glucose (most common sugar)

5
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6
Reactions of Sugars
  • The aldehyde group
  • Aldehydes can be oxidized
  • reducing sugars those that have a free
    aldehyde (most aldehydes) give a positive
    Tollens test (silver mirror)
  • Aldehydes can be reduced

An alditol
7
Biological Redox of Sugars
8
  • Reaction with a Nucleophile
  • Combination of these ideas ? Killiani-Fischer
    synthesis used by Fischer to correlate
    D/L-glyceraldehyde with threose/erythrose
    configurations

9
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10
Reactions (of aldehydes) with Internal
Nucleophiles
  • Glucose forms 6-membered ring b/c all
    substituents are equatorial, thus avoiding
    1,3-diaxial interactions

11
  • Can also get furanoses, e.g., ribose
  • Ribose prefers 5-membered ring (as opposed to
    6) otherwise there would be an axial OH in the
    6-membered ring

12
  • Why do we get cyclic acetals of sugars? (Glucose
    in open form is ltlt 1)
  • Rearrangement reaction we exchange a CO bond
    for a stronger C-O s bond ? ?H is favored
  • There is little ring strain in 5- or 6- membered
    rings
  • ?S there is some loss of rotational entropy in
    making a ring, but less than in an intermolecular
    reaction1 in, 1 out.

significant ve ?S! ??G ?H -
T?S
Favored for hemiacetal
Not too bad for cyclic acetal
13
Anomers
  • Generate a new chiral centre during hemiacetal
    formation (see overhead)
  • These are called ANOMERS
  • ß-OH up (technically, cis to the CH2OH group)
  • a-OH down (technically, trans to the CH2OH group)
  • Stereoisomers at C1 ?diastereomers
  • a- and ß- anomers of glucose can be crystallized
    in both pure forms
  • In solution, MUTAROTATION occurs

14
Mutarotation
15
In solution, with acid present (catalytic), get
MUTAROTATION not via the aldehyde, but oxonium
ion
We know which mechanism operates because the
isotope oxygen-18 is incorporated from H218O
  • At equilibrium, 3862 aß despite a having an
    AXIAL OHWHY? ANOMERIC EFFECT

16
Anomeric Effect
oxonium ion
O lone pair is antiperiplanar to C-O s bond ?
GOOD orbital overlap and hence stabilized by
resonance form (not the case with the ß-anomer)
17
Projections
18
More Reactions of Sugars
  • Reactions of OH group(s)
  • Esterification
  • Ethers

19
b) Ethers (cont)
  1. Acetals

20
c) Acetals (cont)
21
  • These reactions are used for selective protection
    of one alcohol activation of another
    (protecting group chemistry)

1 alcohol is most reactive ?protect first
AZT
22
e.g, synthesis of sucrose (Lemieux, Alberta)
  • Can only couple one wayif we dont protect, get
    all different coupling patterns
  • YET nature does this all of the time enzymes
    hold molecules together in the correct
    orientation
  • Mechanism still goes through an oxonium ion (more
    on this later)

23
Selectivity of Anomer Formation in Glycosides
  • Oxonium ion can often be attacked from both Re
    Si faces to give a mixture of anomers.
  • How do we control this?

24
This reaction provides a clue to how an enzyme
might stabilize an oxonium ion (see later)
25
Examples of Naturally Occurring di- oligo-
Saccharides
Maltose 2 units of glucose a ß sugar a
glycoside 1,4-linkage
Lactose (milk) galactose glucose a ß sugar
ß glycoside 1,4-linkage
26
Sucrose (sugar) glucose fructofuranose a ß
sugar a glycoside 1,2-glycosidic bond
a-1,6-glycosidic bond
Amylopectin (blood cells) an oligosaccharide

a-1,4-glycosidic bond
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