1. CARBOHYDRATES
(SACCHARIDES, SUGARS)

2. (MONOSACCHARIDES,
SIMPLE SUGARS)

3. PHOTOSYNTHESIS

4. Saccharide classification
Monosaccharides
(simple sugars)
Glucose
Mannose
Ribose
Oligosaccharides
Sucrose
Lactose
Maltose
Polysaccharides
Starch
Cellulose
Pectins
Hydrolyze to simple sugars.
Contain many monosugars
linked together
Not hydrolyze to smaller
molecules
Hydrolyze to simple sugars.
Contain 2-10 monosugars
linked together

5. Monosaccharide structures
an aldohexose a ketohexose an aldopentose

6. Naturally occurring D-sugars
(R)-(+)-glyceraldehyde
Configuration at stereogenic center farthest from the carbonyl group
is on the right in Fischer projection

7. D-Aldoses
an aldotriose
5 December 2016
aldotetroses

8. D-Aldoses
aldotetroses
aldopentoses

9. D-Aldoses

10. All Altruists Gladly Make Gum In Gallon Tanks
D-Aldoses
Allose Altrose Glucose Mannose
Gulose Idose Galactose Talose
All Altruists Gladly Make
Gum In Gallon Tanks

11. D-Ketoses
a ketotriose
a ketotetrose
a ketopentose
a ketopentose

12. D-Ketoses
ketopentoses
ketohexoses

13. Cyclic forms of monosugars
In monosugars carbonyl and hydroxyl groups are in the same
molecule, so hemiacetal formed is a 6- or 5-membered ring
with one oxygen atom – pyran or furan analogue

14. Cyclic forms of monosugars
D-glucose, pyranose form
D-fructose, furanose form

15. 6- and 5-membered oxygen heterocycles

16. Interconversion of Fischer and Haworth projections
D-glucose
(Fischer)
D-glucose
(Haworth))

17. Two stereoisomers of pyranose form
(anomers)
α-D-glucopyranose
36%
β-D-glucopyranose
64%
α anomer
β anomer

18. Mutarotation of monosaccharides
α-D-glucopyranose (36%)
[α]D = °
β-D-glucopyranose (64%)
[α]D = +18.7°
At equilibrium [α]D = +52.6°

19. Chair conformations of glucopyranose anomers
α-D-glucopyranose
β-D-glucopyranose

20. Chair conformations of glucopyranose anomers
Anomeric carbon (C1)
Anomeric carbon (C1)
α-D-glucopyranose
β-D-glucopyranose

21. β-D-glucopyranose
Anomeric hydroxyl

22. Physical properties of hexoses
Crystalline solids, non-volatile, decompose at elevated temperature (caramelization)
Polar, very well soluble in water, soluble to some extent in lower alcohols, insoluble in nonpolar organic solvents
Form oversaturated solutions in water (syrups) – difficult for crystallization

23. Chemical properties of hexoses
Enolization (isomerization)
Oxidation
Reduction
Glycoside formation (acetals)
Acylation (esters formation)
Alkylation (ethers formation)
Reactions with nitrogen nucleophiles
Kiliani-Fischer chain lengthening
Wohl degradation (chain shortening)

24. Chemical properties of hexoses
Enolization (isomerization)
D-glucose, D-mannose
Keto-enol tautomerism (base or acid-catalyzed)

25. Chemical properties of hexoses
Oxidation
Tollens
reagent
Fehling
reagent
Ag0
Red solid
Silver mirror

26. Chemical properties of hexoses
Oxidation
Oxidation of aldehyde group of aldose leads to aldonic acid

27. Chemical properties of hexoses
Oxidation
Oxidation of aldehyde and hydroxymethyl groups of aldoses
leads to dicarboxylic aldaric acids

28. Chemical properties of hexoses
Oxidation
Oxidation of hydroxymethyl group of aldose leads to uronic acid

29. Chemical properties of hexoses
Reduction
Reduction of aldehyde group of aldoses leads to alditols

30. Acetal formation from hemiacetal
Cyclic monosugar + alcohol → Glycoside water

31. Chemical properties of hexoses
Glycoside formation
Acetal
Hemiacetal

32. Glycosides in nature
Bearberry
Methylarbutin
Skin-lightening activity

33. Glycosides in nature Salicin Anti-inflammatory activity Willow
Salix alba
Salicin
Anti-inflammatory activity

34. Glycosides in nature
Aglycon
Amygdalin
Cyanogenic glycoside

35. Properties of glycosides
Exist as two distinct anomers - α or β
Do not show reducing properties (ring does not open)
Mutarotation is not possible (ring does not open)
Stable in alkaline aq. solutions (like ethers)
Hydrolyze in acidic aq. solutions into sugar and aglycon

36. Chemical properties of hexoses
Acylation (esters formation)

37. Chemical properties of hexoses
Alkylation (ethers formation)

38. Chemical properties of hexoses
Reactions with nitrogen nucleophiles
Reaction with hydroxylamine leads to D-glucose oxime

39. Chemical properties of hexoses
Reactions with nitrogen nucleophiles
Reaction with phenylhydrazine leads to D-glucose phenylhydrazone

40. Chemical properties of hexoses
Reactions with nitrogen nucleophiles
Reaction with excess of phenylhydrazine leads to D-glucose osazone

41. Chemical properties of hexoses
Reactions with nitrogen nucleophiles
D-glucose osazone can be converted into osone – 1,2-dicarbonyl derivative

42. Kiliani-Fischer chain lengthening of monosugars

43. Kiliani-Fischer chain lengthening of monosugars

44. Wohl degradation (chain shortening) of monosugars

45. GLYCOSIDES Monosugar + alcohol Glycoside + water Aglycon:
4-methoxyphenol
Sugar:
D-glucose

46. OLIGOSACCHARIDES

47. OLIGOSACCHARIDES Cellobiose, a 1,4’-β-glycoside D-Glup-(β 1→4)-D-Glup
Monosugar + monosugar Disaccharide water
1β,4’ glycoside bond
Cellobiose, a 1,4’-β-glycoside
D-Glup-(β 1→4)-D-Glup

48. CELLOBIOSE 1’ 1 4’

49. MALTOSE Maltose, a 1,4’-α-glycoside D-Glup-(α 1→4)-D-Glup
1α,4’ glycoside bond
Maltose, a 1,4’-α-glycoside
D-Glup-(α 1→4)-D-Glup

50. MALTOSE Maltose and cellobiose are diastereoisomers.
The only differrence is the
configuration of glycoside
bond – α in maltose,
β in cellobiose.

51. Cellobiose and maltose are reducing sugars
They exist in two anomeric forms (α and β)
Cellobiose and maltose are
reducing disaccharides.
They reduce Tollens or Fehling reagent
They also show mutarotation

52. LACTOSE (milk sugar) Lactose, a 1,4’-β-galactoside
4-O-(β-D-galactopyranosyl)-D-glucopyranose
Lactose, a 1,4’-β-galactoside
D-Galp-(β 1→4)-D-Glup

53. LACTOSE
(α anomer)
Galactose
Glucose

54. SUCROSE (saccharose, sugar)1 2’
2-O-(α-D-glucopyranosyl)-β-D-fructofuranoside
Sucrose, a 1,2’-glycoside
D-Glup-(1α→2β)-D-Fruf

55. SUCROSE Is sucrose reducing or nonreducing disaccharide? Fructose
Glucose
Glycoside bond
Is sucrose reducing or nonreducing disaccharide?

56. OLIGOSACCHARIDES CYCLODEXTRINS
7 glucose molecules
linked α1-4 form a ring

57. OLIGOSACCHARIDES CYCLODEXTRINS
Outer surface is hydrophilic due to hydroxyl groups
Cavity is hydrophobic and can accomodate lipophilic molecules
Cyclodextrin form inclusion complexes
with numerous compounds
γ-cyclodextrin

58. CYCLODEXTRINS 6 7 8 Prepared by enzymatic cyclization of starch
degradation products 7
Applications:
food industry
pharmaceutical industry
chemical industry
cosmetics
agriculture
environmental engineering
chromatography 8

59. POLYSACCHARIDES
14 January 2019

60. POLYSACCHARIDES CELLULOSE
Large molecules built from hundreds or thousands monosugars linked
through glycoside bonds
CELLULOSE
D-Glucose units linked by β1- 4’ glycoside bonds

61. CELLULOSE Formation of cellulose fibers –
intra- and intermolecular hydrogen
bonds stabilize structure

62. CELLULOSE ACETATE
(artificial fibre)
Applications

63. (Energy storage in plants)
STARCH
(Energy storage in plants)
Two kinds of D-glucose polymers
AMYLOSE
AMYLOPECTIN
Soluble in cold water
Insoluble in cold water

64. AMYLOSE
Linear polymer of D-Glucose units linked by α1- 4’ glycoside bonds

65. AMYLOSE
Spherical model of amylose helix

66. Branched polymer of D-Glucose units
AMYLOPECTIN
Branched polymer of D-Glucose units
linked by α1- 4’ and α1- 6’ glycoside bonds

67. Branched polymer of D-Glucose units
AMYLOPECTIN
Branched polymer of D-Glucose units
linked by α1-4’ and α1-6’ glycoside bonds

68. AMYLOPECTIN
1,6 glycoside bond
1,4 glycoside bond

69. Branched polymer of D-Glucose units
GLYCOGEN
Branched polymer of D-Glucose units
linked by α1- 4’ and α1- 6’ glycoside bonds

70. Comparison of amylose, amylopectin and glycogen

71. Other important carbohydrates
Pentoses
Structural fragment of RNA
Structural fragment of DNA

72. Other important carbohydrates (β-L-6-deoxygalactose)
Deoxysugars
β-L-Fucose
(β-L-6-deoxygalactose)

73. Other important carbohydrates
Aminosugars
α-D-glucosamine

74. Other important carbohydrates
Aminosugars
β-D-N-acetylglucosamine (monomer of polysaccharide - chitin)

75. CHITIN
GlcNAc units linked by β1→4’ glycoside bonds

76. Gentamicin
(antibiotic)

77. Streptomycin
(antibiotic)

78. Carbohydrates on cell surfaces
Human blood group types

79. Structures of blood group antigenic determinants
Group B

80. Structures of blood group antigenic determinants

81. Red blood cell compatibility
Recipient[1]
Donor[1] O- O+ A− A+ B− B+
AB−
AB+ O−
compatible
incompatible