Chemistry of Carbohydrates PDF

Summary

This document is about the chemistry of carbohydrates, including their structure, properties, and functions. It covers topics ranging from nomenclature to different types of carbohydrates found in food. The document also discusses various aspects of carbohydrate metabolism.

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2 | Chemistry of
Carbohydrates

Chapter 7: Chapter 1:
Carbohydrates and Chemistry of
Glycobiology Carbohydrates
Carbohydrates

▶ Named so because many have formula Cn(H2O)n
▶ Produced from CO2 and H2O via photosynthesis in plants
▶ Range from as small as glyceraldehyde (Mw = 90 g/mol)
to as large as amylopectin (Mw > 200,000,000 g/mol)
▶ Fulfill a variety of functions, including:
▶ energy source and energy storage
▶ structural component of cell walls and exoskeletons
▶ informational molecules in cell-cell signaling

▶ Can be covalently linked with proteins and lipids
 Common CHO and their
Food Sources

Glycogen
Cellulose
Carbohydrates

▶ Basic nomenclature:
▶ number of carbon atoms in the carbohydrate + -ose
▶ example: three carbons = triose
▶ Common functional groups:
▶ All carbohydrates initially had a carbonyl functional group.
▶ aldehydes = aldose
▶ ketones = ketose
 Monosaccharides Found in Food

Six
Seven
Monosaccharides Can Be Constitutional Isomers
An aldose is a carbohydrate with aldehyde functionality.
A ketose is a carbohydrate with ketone functionality.
 Carbohydrates Can Be Stereoisomers
Epimers are stereoisomers that differ at only one chiral center.
Epimers are NOT mirror images, and therefore are NOT
enantiomers.
Epimers are diastereomers; diastereomers have different
physical properties (i.e., water solubility, melting temp).
example: D-Threose is the C-2 epimer of D-erythrose.
Both are D sugars because they both have the same
orientation around the last chiral carbon in the chain.
 Epimers
D-Mannose and D-galactose are both epimers of
D-glucose.
D-Mannose and D-galactose vary at more than one
chiral center and are diastereomers, but not epimers.
Monosaccharides Have Straight and Ring Structures

-D-Glucopyranose
 Cyclization of
Monosaccharides
The nucleophilic alcohol attacks
the electrophilic carbonyl
carbon, allowing formation of a
hemiacetal.
As a result, the linear
carbohydrate forms a ring
structure.
At the completion of this
structure, the carbonyl carbon is
reduced to an alcohol
The orientation of the alcohol
around the carbon is variable
and transient.
 Cyclization of Monosaccharides

▶ Pentosesand hexoses readily undergo
intramolecular cyclization.
▶ The former carbonyl carbon becomes a new chiral
center, called the anomeric carbon.
▶ When the former carbonyl oxygen becomes a hydroxyl
group, the position of this group determines if the
anomer is  or .
▶ Ifthe hydroxyl group is on the opposite side (trans) of
the ring as the CH2OH moiety, the configuration is .
▶ Ifthe hydroxyl group is on the same side (cis) of the
ring as the CH2OH moiety, the configuration is .
 Cyclization of Monosaccharides:
Pyranoses and Furanoses

▶ Six-membered oxygen-containing rings are
called pyranoses after the pyran ring structure.
▶ Five-membered oxygen-containing rings are
called furanoses after the furan ring structure.
▶ Theanomeric carbon is usually drawn on the
right side.
 Conformational Formulas of Cyclized
Monosaccharides
Cyclohexane rings have “chair” or “boat” conformations.
Pyranose rings favor “chair” conformations.
Multiple “chair” conformations are possible but require energy
for interconversion (~46 kJ/mole).
Reducing Sugars

▶ Reducing sugars have a free anomeric carbon.
▶ Aldehyde can reduce Cu2+ to Cu+ (Fehling’s test).
▶ Aldehyde can reduce Ag+ to Ag0 (Tollens’ test).
▶ It allows detection of reducing sugars, such as glucose.
▶ Modern detection techniques use colorimetric and
electrochemical tests.
 Colorimetric Glucose Analysis

▶ Enzymatic methods are used to
-D-Gluconolactone
-D-Glucose quantify reducing sugars such as
CH2OH CH2OH glucose.
O OH
Glucose oxidase
O ▶ The enzyme glucose oxidase
OH OH O
catalyzes the conversion of
HO HO glucose to glucono--lactone
OH O2 OH
and hydrogen peroxide.
▶ Hydrogen peroxide oxidizes
H2O2
NH organic molecules into highly
OCH3 NH2 colored compounds.
2 H 2O OCH3
▶ Concentrations of such
compounds is measured
colorimetrically.
Peroxidase

OCH3
NH OCH3
NH2

Oxidized Reduced Electrochemical detection is
o-dianisidine
(bright orange)
o-dianisidine
(faint orange) used in portable glucose
sensors.
Disaccharides and the Glycosidic Bond
▶ Two sugar molecules can be joined via a
glycosidic bond between an anomeric carbon
and a hydroxyl carbon.
▶ The glycosidic bond (an acetal) between
monomers is more stable and less reactive than
the hemiacetal at the second monomer.
▶ The second monomer, with the hemiacetal, is
reducing.
▶ The anomeric carbon involved in the glycosidic
linkage is nonreducing.
▶ Disacharides can be named by the organization
and linkage or a common name.
▶ The disaccharide formed upon condensation of
two glucose molecules via a 1  4 bond is
described as α-d-glucopyranosyl-(14)-D-
glucopyranose.
▶ The common name for this disaccharide is
maltose.
Nonreducing Disaccharides

▶ Two sugar molecules can
be also joined via a
glycosidic bond between
two anomeric carbons.
▶ The product has two
acetal groups and no
hemiacetals.
▶ There are no reducing
ends; this is a nonreducing
sugar.
Polysaccharides
▶ Natural carbohydrates are usually found as polymers.
▶ These polysaccharides can be:
▶ homopolysaccharides (one monomer unit)
▶ heteropolysaccharides (multiple monomer units)
▶ linear (one type of glycosidic bond)
▶ branched (multiple types of glycosidic bonds)
▶ Polysaccharides do not have a defined molecular weight.
▶ This is in contrast to proteins because, unlike
proteins, no template is used to make
polysaccharides.
▶ Polysaccharides are often in a state of flux; monomer
units are added and removed as needed by the
organism.
Common Polysaccharides
 Homopolymers of Glucose:
Glycogen

Glycogen is a branched homopolysaccharide of
glucose.
– Glucose monomers form (1 4) linked chains.
– There are branch points with (1 6) linkers every
8–12 residues.
– Molecular weight reaches several millions.
– It functions as the main storage polysaccharide in
animals.
 Homopolymers of Glucose:
Starch
Starch is a mixture of two homopolysaccharides of
glucose.
Amylose is an unbranched polymer of (1 4)
linked residues.
Amylopectin is branched like glycogen, but the
branch points with (1 6) linkers occur every
24–30 residues.
Molecular weight of amylopectin is up to 200
million.
Starch is the main storage polysaccharide in plants.
Glycosidic Linkages in Glycogen and Starch
Mixture of Amylose and
Amylopectin in Starch
Dextrins are Hydrolysis Products of Starch
▶ Low-molecular-weight carbohydrates
▶ Polymers or D-glucose linked by α-(1→4) or α-
(1→6) glycosidic bonds
▶ Produced by the partial hydrolysis of starch or
glycogen (salivary amylase and similar
enzymes)
▶ Can be produced in the gut and in cooking
starch or glycogen
▶ Can be used as water-soluble adhesives (glues)
because of formation of a sticky solution in
water
▶ Further hydrolysis leads limit dextrins
(erythrodextrin) and later to achrodextrins
▶ Achrodextrins are further hydrolyzed to
maltose and glucose
 Metabolism of Glycogen and Starch

▶ Glycogenand starch are insoluble due to their high
molecular weight and often form granules in cells.
▶ Granulescontain enzymes that synthesize and
degrade these polymers.
▶ Glycogenand amylopectin have one reducing end
but many nonreducing ends.
▶ Enzymaticprocessing occurs simultaneously in
many nonreducing ends.
 Homopolymers of Glucose:
Cellulose

▶ Cellulose is a linear homopolysaccharide of
glucose.
▶ Glucose monomers form (1 4) linked chains.
▶ Hydrogen bonds form between adjacent monomers.
▶ There are additional H-bonds between chains.
▶ Structure is now tough and water insoluble.
▶ It is the most abundant polysaccharide in nature.
▶ Cotton is nearly pure fibrous cellulose.
 Cellulose Metabolism

▶ The fibrous structure and water insolubility make
cellulose a difficult substrate to act upon.
▶ Most animals cannot use cellulose as a fuel source
because they lack the enzyme to hydrolyze (1 4)
linkages.
▶ Fungi, bacteria, and protozoa secrete cellulase,
which allows them to use wood as source of glucose.
▶ Ruminants and termites live symbiotically with
microorganisms that produce cellulase and are able
to absorb the freed glucose into their bloodstreams.
▶ Cellulases hold promise in the fermentation of
biomass into biofuels.
 Chitin Is a Homopolysaccharide
Chitin is a linear homopolysaccharide of N-acetylglucosamine.
– N-acetylglucosamine monomers form (1 4)-linked
chains.
– forms extended fibers that are similar to those of cellulose
– hard, insoluble, cannot be digested by vertebrates
– structure is tough but flexible, and water insoluble
– found in cell walls in mushrooms and in exoskeletons of
insects, spiders, crabs, and other arthropods
Inulin Is Made from Fructose

▶ Plant polysaccharide
n~35
▶ Made from fructose units
▶ Chain-terminating glucose
▶ Sweet taste
▶ Present in roots for energy
storage
▶ Most plants that synthesize
inulin do not store energy in
the form of starch
▶ Good source of dietary fiber
 Agar and Agarose

▶ Agar is a branched heteropolysaccharide
composed of agarose and agaropectin.
▶ Agar serves as a component of cell wall in
some seaweeds.
▶ Agar solutions form gels that are commonly
used in the laboratory as a surface for growing
bacteria.
▶ Agarose solutions form gels that are commonly
used in the laboratory for separation DNA by
electrophoresis.
Agarose Is a Heteropolysaccharide
 Glycosaminoglycans
▶ Linear polymers of repeating disaccharide units
▶ One monomer is either:
▶ N-acetyl-glucosamine or
▶ N-acetyl-galactosamine
▶ Negatively charged
▶ uronic acids (C6 oxidation)
▶ sulfate esters
▶ Extended hydrated molecule
▶ minimizes charge repulsion
▶ Forms meshwork with fibrous proteins to form
extracellular matrix
▶ connective tissue
▶ lubrication of joints
 Heparin and Heparan Sulfate

▶ Heparin is linear polymer, 3–40 kDa.
▶ Heparan sulfate is heparin-like polysaccharide
but attached to proteins.
▶ Highest negative-charge density biomolecules
▶ Prevent blood clotting by activating protease
inhibitor antithrombin
▶ Binding to various cells regulates development
and formation of blood vessels.
▶ Can also bind to viruses and bacteria and
decrease their virulence
 TABLE 7-2 Structures and Roles of Some Polysaccharides
Size (number of
monosaccharide
Primer Typea Repeating unitb units) Roles/significance
Starch Energy storage: in plants

Amylose Homo- (α1S4) Glc, linear 50–5,000
Amylopectin Homo- (α1S4) Glc, with (α1S6) Up to 106
Glc branches every 24–30
residues

Glycogen Homo- (α1S4) Glc, with (α1S6) Up to 50,000 Energy storage: in bacteria and animal
Glc branches every 8–12 cells
residues

Cellulose Homo- (β1S4) Glc Up to 15,000 Structural: in plants, gives rigidity and
strength to cell walls

Chitin Homo- (β1S4) GlcNAc Very large Structural: in insects, spiders,
crustaceans, gives rigidity and strength
to exoskeletons

Dextran Homo- (α1S6) Glc, with (α1S3) Wide range Structural: in bacteria, extracellular
branches adhesive
Peptidoglycan Hetero-; peptides 4)Mur2Ac(β1S4) Very large Structural: in bacteria, gives rigidity and
attached GlcNAc(β1 strength to cell envelope

Agarose Hetero- 3)D-Gal (β1S4)3,6- 1,000 Structural: in algae, cell wall material
anhydro-L-Gal(α1
Hyaluronan (a Hetero-; acidic 4)GlcA (β1S3) GlcNAc(β1 Up to 100,000 Structural: in vertebrates, extracellular
glycosaminoglycan) matrix of skin and connective tissue;
viscosity and lubrication in joints
aEach polymer is classified as a homopolysaccharide (homo-) or heteropolysaccharide (hetero-).
bThe abbreviated names for the peptidoglycan, agarose, and hyaluronan repeating units indicate that the polymer contains repeats of this
disaccharide unit. For example, in peptidoglycan, the GlcNAc of one disaccharide unit is (β1S4)-linked to the first residue of the next disaccharide
unit.