Carbohydrates and Glycobiology Lecture Notes PDF

Summary

These lecture notes cover carbohydrates and glycobiology, including topics like monosaccharides, disaccharides, and polysaccharides. Suitable for an undergraduate biochemistry course.

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Chap 7. Carbohydrates and
Glycobiology

Crystal Zhang Glassford, Ph.D.
Southern Adventist University
Biochemistry I
 Devotional thoughts

Matthew 22:37
You shall love your God with all your heart,
with all your soul, and with all your mind.
 Carbohydrates

carbohydrates = aldehydes or ketones with at
least two hydroxyl groups, or substances that yield
such compounds on hydrolysis
(polyhydroxy aldehydes or ketones)

many carbohydrates have the empirical formula
(CH2O)n
 Classes of Carbohydrates
monosaccharides = simple sugars, consist of a single
polyhydroxy aldehyde or ketone unit
– example: D-glucose

oligosaccharides = short chains of monosaccharide
units, or residues, joined by glycosidic bonds

disaccharides = oligosaccharides with two
monosaccharide units
– example: sucrose (D-glucose and D-fructose)

polysaccharides = sugar polymers with 10+
monosaccharide units
– examples: cellulose (linear), glycogen (branched)
7.1 Monosaccharides and
Disaccharides
 The Two Families of Monosaccharides Are
Aldoses and Ketoses
aldose = carbonyl group at an end of the carbon chain (in an aldehyde
group)
ketose = carbonyl group at any other position (in a ketone group)
trioses hexoses pentoses

backbones of monosaccharides:
unbranched carbon chains with single bonds linking all carbon
atoms
one of the carbon atoms is double-bonded to an oxygen atom to
form a carbonyl group
other carbon atoms are bonded to a hydroxyl group
Monosaccharides Have Asymmetric
Centers

all monosaccharides (except dihydroxyacetone) contain
1+ chiral carbon atom
– occur in optically active isomeric forms

enantiomers = two different optical isomers that are
mirror images

in general, a molecule with n chiral centers can have 2n
stereoisomers
 Fischer Projection Formulas
used to represent three-
dimensional sugar structures
on paper

bonds drawn horizontally
indicate bonds that project
out of the plane of the paper

bonds drawn vertically
project behind the plane of
the paper
 D Isomers and L Isomers
reference carbon = chiral center most distant from the
carbonyl carbon

two groups of stereoisomers:
– D isomers = configuration at reference carbon is the
same as D-glyceraldehyde
on the right (dextro) in a projection formula
most hexoses of living organisms
– L isomers = configuration at reference carbon is the
same as L-glyceraldehyde
on the left (levo) in a projection formula
 D-Aldoses

* *

* * *

*those are the ones you need to know Fisher Projections
 D-Ketoses

*those are the ones you
* need to know Fisher
Projections

*
 Epimers
epimers = two sugars that differ only in the
configuration around one carbon atom

carbons are numbered beginning at the end of the chain
near the carbonyl group
 The Common Monosaccharides
Have Cyclic Structures

in aqueous solution, aldotetroses and all
monosaccharides with 5+ backbone carbon atoms occur
as cyclic structures
– covalent bond between the carbonyl group and the
oxygen of a hydroxyl group
 Hemiacetals and Hemiketals

hemiacetals or hemiketals = derivatives formed by a
general reaction between alcohols and aldehydes or
ketones
– product of the first alcohol molecule addition
– a five- or six-membered ring forms if the —OH and
carbonyl groups are on the same molecule

acetal or ketal = product of the second alcohol
molecule addition
– forms a glycosidic bond
Formation of Hemiacetals and
Hemiketals
 α and β Stereoisomeric
Configurations
reaction with the first alcohol molecule creates an
additional chiral center (the carbonyl carbon)

produces either of two stereoisomeric configurations: α
and β

anomers = isomeric forms of monosaccharides that
differ only in their configuration about the hemiacetal or
hemiketal carbon atom

anomeric carbon = the carbonyl carbon atom
Formation of the Two Cyclic Forms
of D-Glucose

reaction between
the aldehyde group
at C-1 and the
hydroxyl group at C-
5 forms a
hemiacetal linkage

mutarotation = the
interconversion of α
and β anomers
 Pyranoses and Furanoses
pyranoses = six-membered
ring compounds
– form when the hydroxyl
group at C-5 reacts with
the keto group at C-1
furanoses = five-membered
ring compounds
– form when the hydroxyl
group at C-5 reacts with
the keto group at C-2
 Haworth Perspective Formulas
Haworth perspective
formulas = more
accurate representation
of cyclic sugar structure
than Fischer projections
– six-membered ring is
tilted to make its plane
almost perpendicular
to that of the paper
– bonds closest to the
reader are drawn
thicker than those
farther away
Converting D-Hexose Fischer Projections
to Haworth Perspective Formulas
step 1: draw the six-membered ring (five carbons, and one oxygen
at the upper right)
step 2: number the carbons in a clockwise direction beginning with
the anomeric carbon
step 3: place the hydroxyl groups
– hydroxyl groups on the right in a Fischer projection are placed
pointing down and those on the left are placed pointing up
step 4: place the terminal —CH2OH group
– projects upward for the D enantiomer, downward for the L
enantiomer
step 5: place the anomeric hydroxyl group
– for a β structure, the hydroxyl group is placed on the same side
of the ring as C-6
– for an α structure, it is placed on the opposite side
Organisms Contain a Variety of Hexose
Derivatives

Identifying hexose derivatives is required!
 Aldonic and Uronic Acids

aldonic acids = form following oxidation of the
carbonyl carbon of aldoses
uronic acids = form following oxidation at C-6
both form stable intramolecular esters called lactones
 Phosphorylated Derivatives

some sugar intermediates are phosphate esters
– example: glucose 6-phosphate

stable at neutral pH and bear a negative charge

functions to trap sugar inside the cell because most
cells do not have membrane transporters for
phosphorylated sugars
 Sugars That Are, or Can Form,
Aldehydes Are Reducing Sugars
reducing sugars = undergo a characteristic redox
reaction where free aldehyde groups react with Cu2+
under alkaline condition
– reduction of Cu2+ to Cu+ forms a brick-red precipitate

ketoses that can tautomerize to form aldehydes are also
reducing sugars
 Formation of Maltose
O-glycosidic bond = covalent
linkage joining two
monosaccharides
– formed when a hydroxyl
group of one sugar
molecule reacts with the
anomeric carbon of the
other
– readily hydrolyzed by acid

formation of a glycosidic bond
renders a sugar nonreducing

reducing end = the end of a
disaccharide or polysaccharide
chain with a free anomeric Free anomeric carbon
carbon
Naming Reducing Oligosaccharides
step 1: with the nonreducing end on the left, give the
configuration (α or β) at the anomeric carbon joining the
first unit to the second

step 2: name the nonreducing residue using “furano” or
“pyrano”

step 3: indicate in parentheses the two carbon atoms
joined by the glycosidic bond, with an arrow connecting
the two numbers

step 4: name the second residue and repeat for
additional residues
 Symbols and Abbreviations for
Monosaccharides and Derivatives
 Three Common Disaccharides

lactose is a reducing
disaccharide

sucrose and trehalose
are nonreducing sugars
 Reducing sugar
A reducing sugar is any sugar that is capable of acting as a reducing
agent. In an alkaline solution, a reducing sugar forms
some aldehyde or ketone, which allows it to act as a reducing agent,
in Benedict's reagent, the sugar becomes a carboxylic acid.
Ketoses must first tautomerize to aldoses before they can act as
reducing sugars.
The common dietary monosaccharides:
– galactose, glucose and fructose are all reducing sugars.
Disaccharides:
- Nonreducing: sucrose and trehalose; have glycosidic bonds between
their anomeric carbons and thus cannot convert to an open-chain form
with an aldehyde group; they are stuck in the cyclic form.
- Reducing: lactose and maltose; have only one of their two anomeric
carbons involved in the glycosidic bond, while the other is free and can
convert to an open-chain form with an aldehyde group.

https://en.wikipedia.org/wiki/Reducing_sugar
Learning objectives
 7.2 Polysaccharides
& 7.3-1 Glycoconjugates
 Devotional thoughts

Micah 7:18
Who is a God like You, pardoning iniquity
and passing over the transgression of the
remnant of His heritage? He does not
retain His anger forever, because He
delights in mercy.
 Polysaccharides

most carbohydrates in nature occur as polysaccharides
(Mr > 20,000)

also called glycans
 Homopolysaccharides and
Heteropolysaccharides
homopolysaccharides =
contain only a single
monomeric sugar species
– serve as storage forms
and structural
elements

heteropolysaccharides =
contain 2+ kinds of
monomers
– provide extracellular
support
Polysaccharides Generally Do Not Have
Defined Lengths or Molecular Weights

this distinction between proteins and polysaccharides is
a consequence of the mechanisms of assembly

there is no template for polysaccharide synthesis

the program for polysaccharide synthesis is intrinsic to
the enzymes that catalyze the polymerization of
monomer units
Some Homopolysaccharides Are
Storage Forms of Fuel
storage polysaccharides = starch in plant cells and
glycogen in animal cells

starch and glycogen molecules are heavily hydrated
because they have many exposed hydroxyl groups
available to hydrogen bond
 Starch and Glycogen
starch = contains two types of glucose polymer,
amylose and amylopectin
– amylose = long, unbranched chains of D-glucose
residues connected by (α1→4) linkages
– amylopectin = larger than amylose with (α1→4)
linkages between glucose residues and highly
branched due to (α1→6) linkages

glycogen = polymer of (α1→4)-linked glucose
subunits, with (α1→6)-linked branches
– more extensively branched
– more compact than starch
 Structure of Starch and Glycogen
Amylose (plants) and glycogen (animal)

Amylopectin or glycogen
Storage of Glucose as Polymers
Avoids High Osmolarity
hepatocytes in the fed state store glycogen equivalent
to a glucose concentration of 0.4 M

0.4 M glucose in the cytosol would elevate the
osmolarity
– the resulting osmotic entry of water might rupture
the cell
Q: Why is it logical for sugars to be added to only one
end of glycogen, making them excellent molecules for
glucose storage?

Answer: Because there are many nonreducing ends on one molecule,
allowing rapid glucose storage and release.
Some Homopolysaccharides Serve
Structural Roles
cellulose = tough, fibrous, water-insoluble substance
– linear, unbranched homopolysaccharide,
consisting of 10,000 to 15,000 D-glucose units
– glucose residues have the β configuration
– linked by (β1→4) glycosidic bonds
– animals do not have the enzyme to hydrolyze
(β1→4) glycosidic bonds
 Chitin

chitin = linear homopolysaccharide composed of N-
acetylglucosamine residues in (β1→4) linkage
– acetylated amino group makes chitin more
hydrophobic and water-resistant than cellulose
 Steric Factors and Hydrogen Bonding
Influence Homopolysaccharide Folding

three-dimensional structures stabilized by weak
interactions within or between molecules
– hydrogen bonding is especially important due to
the high number of hydroxyl groups in
polysaccharides

free rotation about both C—O bonds linking the
residues is limited by steric hindrance by substituents
Different Energetic Conformation of
a Disaccharide
bulkiness and
electronic effects
at the anomeric
carbon place
constraints on φ
and ψ
 Helical Structure of Starch and
Glycogen
most stable three-
dimensional structure
for the (α1→4)-linked
chains of starch and
glycogen
– six residues/turn
Shown as blue in iodine
test

amylopectin
 Linear Structure of Cellulose

most stable
conformation is
a straight,
extended chain
– each chair is
turned 180°
relative to its
neighbors

Q: most animals cannot use Found in cell walls of plants
cellulose as fuel source. Explain
why?
 Peptidoglycan Reinforces the
Bacterial Cell Wall

peptidoglycan = rigid
component of bacterial
cell walls
– heteropolymer of
alternating (β1→4)-
linked N-
acetylglucosamine
and N-acetylmuramic
acid residues
– cross-linked by short
peptides
 Glycosaminoglycans Are
Heteropolysaccharides of the Extracellular
Matrix
extracellular matrix (ECM) = gel-like material in the
extracellular space of tissues that holds cells together
and provides a porous pathway for nutrient and O2
diffusion
– composed of an interlocking meshwork of
heteropolysaccharides (ground substance) and
fibrous proteins

basement membrane (specialized ECM) also contains
heteropolysaccharides
 Repeating Units of
Glycosaminoglycans of ECM

glycosaminoglycans =
heteropolysaccharides in ECM
– linear polymers composed of
repeating disaccharide units
– one monosaccharide is always
either N-acetylglucosamine or
N-acetylgalactosamine and the
other is usually a uronic acid
– unique to animals and bacteria
– some contain esterified sulfate
groups
 Types of Glycosaminoglycans
hyaluronan (hyaluronic acid) = alternating residues of
D-glucuronic acid and N-acetylglucosamine

chondroitin sulfate, dermatan sulfate, keratan
sulfate, and heparan sulfate differ from hyaluronan in
three respects:
– generally much shorter polymers
– covalently linked to specific proteins (proteoglycans)
– one or both monomer units differ from hyaluronan

provide viscosity, adhesiveness, and tensile strength to
the extracellular matrix
 Heparan Sulfate
contains variable, nonrandom arrangements of sulfated
and nonsulfated sugars

sulfated residues gives the molecule the ability to
interact specifically with proteins

Heparin
– highly sulfated, intracellular form of heparan sulfate produced
primarily by mast cells

– used as a therapeutic agent to inhibit coagulation of blood
through its capacity to bind the protease inhibitor antithrombin
 Structure and Roles of Some
Polysaccharides
Table 7-2 Structures and Roles of Some Polysaccharides
Polymer Type Repeating unit Size (number of Roles/significance
monosaccharide units)
Starch: Homo- (𝛼1→4)Glc, 50-5,000 Energy storage: in plants
Amylose linear

Starch: Homo- (𝛼1→4)Glc, Up to 106 Energy storage: in plants
Amylopectin with (𝛼1→6)Glc
branches every
24-30 residues

Glycogen Homo- (𝛼1→4)Glc, Up to 50,000 Energy storage: in bacteria and animal
with (𝛼1→6)Glc cells
branches every
8-12 residues

Cellulose Homo- (𝛽1→4)Glc Up to 15,000 Structural: in plants, gives rigidity and
strength to cell walls
Chitin Homo- (𝛽1→4)GlcNAc Very large Structural: in insects, spiders, crustaceans,
gives rigidity and strength to exoskeletons
Dextran Homo- (𝛼1→6)Glc, Wide range Structural: in bacteria, extracellular
with (𝛼1→3) adhesive
branches

Peptidoglycan Hetero-; peptides 4)Mur2Ac(𝛽1→4) Very large Structural: in bacteria, gives rigidity and
attached GlcNAc (𝛽1 strength to cell envelope
Hyaluronan (a glycosaminoglycan) Hetero-; acidic 4)GlcA(𝛽1→3) Up to 100,000 Structural: in vertebrates, extracellular
GlcNAc (𝛽1 matrix of skin and connective tissue;
viscosity and lubrication in joints
 Glycoconjugate
glycoconjugate =
biologically active
molecule
consisting of an
informational
carbohydrate
joined to a protein
or lipid
 Proteoglycans
proteoglycans = macromolecules of the cell surface
or ECM consisting of 1+ sulfated glycosaminoglycan
chain(s) joined covalently to a membrane protein or
secreted protein
– major component of all extracellular matrices
 Glycoproteins

glycoproteins = have one or several oligosaccharides
joined covalently to a protein
– found on the outer face of the plasma membrane, in
ECM, in blood, and in organelles (Golgi complexes,
secretory granules, and lysosomes)
– oligosaccharide portions are heterogenous and rich
in information
Glycolipids and Glycosphingolipids

glycolipids = plasma membrane components in which
the hydrophilic head groups are oligosaccharides

glycosphingolipids = class of glycolipids with specific
backbone structure
– neurons are rich in glycosphingolipids
– play a role in signal transduction
Learning objectives