Carbohydrates: Structure, Derivatives, and Classification PDF

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This document is a presentation on carbohydrates, covering their structure, classification, functions, and derivatives. It provides a comprehensive overview of various types of carbohydrates and their importance in biological systems.

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Carbohydrates: Structure of
Monosaccharides and Carbohydrate
Derivatives
Dr. Burak DURMAZ
[email protected]
Near East University, Faculty of Medicine, Department of Medical Biochemistry
 carbohydrates

How does the structure of the carbohydrates we
consume affect the speed at which our body
converts them into energy?
For example, when you consume a food rich in
simple sugars versus one rich in complex
carbohydrates, how and how quickly does your body
access that energy?
 CARBOHYDRATES
Carbohydrates are polyhydroxy aldehydes or
ketones, or substances that yield such compounds on
hydrolysis.
Many, but not all, carbohydrates have the empirical
formula (CH2O)n, some also contain nitrogen,
phosphorus, or sulfur.
Carbohydrates are the most abundant biomolecules
on the Earth. Each year, photosynthesis converts
more than 100 billion tons of CO2 and H2O into
cellulose and other plant products.
 FUNCTIONS of CARBOHYDRATES

1. Certain carbohydrates, eg. sugar and starch, are
important for diet, and the oxidation of
carbohydrates is the central energy-yielding
pathway in non-photosynthetic cells.
2. Insoluble carbohydrate polymers (glycans) serve as
structural and protective elements in the cell walls
of bacteria and plants, and in the connective tissue
of animals.
 FUNCTIONS of CARBOHYDRATES
3. Some carbohydrate polymers lubricate skeletal
joints and participate in recognition and adhesion
between cells.
4. Complex carbohydrate polymers covalently bound
to proteins or lipids act as signals that determine
intracellular location or metabolic fate of these
molecules.
CLASSIFICATION of CARBOHYDRATES
 CLASSIFICATION of CARBOHYDRATES
1. Monosaccharides, or simple sugars, consist of a single
polyhydroxy aldehyde or ketone unit. The most abundant
monosaccharide in nature is the six-carbon sugar D-glucose,
sometimes referred to as dextrose. Monosaccharides of more
than four carbons tend to have cyclic structures.
2. Disaccharides (such as maltose, lactose, and sucrose) consist
of two monosaccharides joined covalently by an O-glycosidic
bond, which is formed when a hydroxyl group of one sugar
reacts with the anomeric carbon of the other. This reaction
represents the formation of an acetal from a hemiacetal
(such as glucopyranose) and an alcohol (a hydroxyl group of
the second sugar molecule).
 CLASSIFICATION of CARBOHYDRATES
3. Oligosaccharides consist of short chains of monosaccharide
units, or residues, joined by characteristic linkages called
glycosidic bonds. In cells, most oligosaccharides consisting of
three or more units do not occur as free entities but are
joined to nonsugar molecules (lipids or proteins) in
glycoconjugates.
4. Polysaccharides are sugar polymers containing more than 20
or so monosaccharide units, and some have hundreds or
thousands of units. Some polysaccharides, such as cellulose,
are linear chains; others, such as glycogen, are branched.
Both glycogen and cellulose consist of recurring units of D-
glucose, but they differ in the type of glycosidic linkage and
consequently have strikingly different properties and
biological roles.
CLASSIFICATION of CARBOHYDRATES
Classification Based on Functional Group
1. Aldoses contain aldehyde group
2. Ketoses contain keto group

Classification Based on Carbon Skeleton
1. Trioses contain 3 carbon atoms
2. Tetroses contain 4 carbon atoms
3. Pentoses contain 5 carbon atoms
4. Hexoses contain 6 carbon atoms
5. Heptoses contain 7 carbon atoms
 Monosaccharides are either aldose or ketose

If the carbonyl group is at an end of the carbon chain (that is, in an
aldehyde group) the monosaccharide is an aldose.
If the carbonyl group is at any other position (in a keto group)
the monosaccharide is a ketose.
The simplest monosaccharides are the two three-carbon trioses:
glyceraldehyde, an aldotriose, and dihydroxyacetone, a ketotriose.
CLASSIFICATION of CARBOHYDRATES
Monosaccharides are Asymmetric Compounds

All the monosaccharides except dihydroxyacetone
contain one or more asymmetric (chiral) carbon
atoms and thus occur in optically active isomeric
forms.
The simplest aldose, glyceraldehyde, contains one
chiral center (the middle carbon atom) and therefore
has two different optical isomers, stereoisomers or
enantiomers.
Monosaccharides are Asymmetric Compounds
By convention, one of
these two forms is
designated the
D isomer, the other
the L isomer. To
represent three-
dimensional sugar
structures on paper,
we often use Fischer
projection formulas.
Compounds containing chiral center are optically active;
they rotate the plane of the polarized light (are either
dextrorotatory, d or levorotatory, l).
 SUGARS HAVE OPTICAL ACTIVITY
All monosaccharides except
dihydroxyacetonephosphate have
at least one assymetric (chiral)
carbon. They are optically active.
They rotate the plane of polarized
light.
 Stereoisomers
In general, a molecule with n chiral centers can have 2n
stereoisomers. Glyceraldehyde has 21 = 2; the aldohexoses, with
four chiral centers, have 24 =16 stereoisomers.
The stereoisomers of monosaccharides of each carbon-chain
length can be divided into two groups that differ in the
configuration about the chiral center most distant from the
carbonyl carbon. Those in which the configuration at this reference
carbon is the same as that of D-glyceraldehyde are designated
D isomers, and those with the same configuration as
L-glyceraldehyde are L isomers.
When the hydroxyl group on the reference carbon is on the right in
the projection formula, the sugar is the D isomer; when on the left,
it is the L isomer. Of the 16 possible aldohexoses, eight are D forms
and eight are L. Most of the hexoses of living organisms are D
isomers.
Stereoisomers
The stereoisomers of monosaccharides
of each carbon-chain length can be
divided into two groups that differ in
the configuration about the chiral
center most distant from the carbonyl
carbon.
Those in which the configuration at this
reference carbon is the same as that of
D-glyceraldehyde are designated
D isomers, and those with the same
configuration as L-glyceraldehyde are
L isomers.
When the hydroxyl group on the
reference carbon is on the right in the
projection formula, the sugar is the
D isomer; when on the left, it is the
L isomer. Of the 16 possible
aldohexoses, eight are D forms and
eight are L. Most of the hexoses of
living organisms are D isomers.
Stereoisomers
Stereoisomers
Stereoisomers
Stereoisomers
 EPIMERS

The carbons of a sugar are numbered beginning at the end of the chain
nearest the carbonyl group. Each of the eight D-aldohexoses, which differ in
the stereochemistry at C-2, C-3, or C-4, has its own name: D-glucose, D-
galactose, D-mannose, and so forth. Two sugars that differ only in the
configuration around one carbon atom are called epimers.
Some sugars occur naturally in their L form; examples are L-arabinose and the
L isomers of some sugar derivatives that are common components of
glycoconjugates.
Formation of hemiacetals and hemiketals
Aldoses and ketoses are not mainly found in straight-
chain forms. In aqueous solution, aldotetroses and all
monosaccharides with five or more carbon atoms in the
backbone occur predominantly as cyclic (ring)
structures in which the carbonyl group has formed a
covalent bond with the oxygen of a hydroxyl group
along the chain.

The formation of these ring structures is the result of a
general reaction between alcohols and aldehydes or
ketones to form derivatives called hemiacetals or
hemiketals which contain an additional asymmetric
carbon atom and thus can exist in two stereoisomeric
forms.
Formation of hemiacetals and hemiketals

An aldehyde can form a hemiacetal with an alcohol. An
additional alcohol is used to form an acetal.

An ketone can form a hemiketal with an alcohol. An
additional alcohol is used to form a ketal.
These reactions are reversible.
 Monosaccharides Have Cyclic Structures
For example, D-glucose exists in
solution as an intra-molecular
hemiacetal in which the free
hydroxyl group at C-5 has
reacted with the aldehydic C-1,
rendering the latter carbon
asymmetric and producing two
stereoisomers, designated a
and b. These six-membered ring
compounds are called
pyranoses because they
resemble the six membered ring
compound pyran. The
systematic names for the two
ring forms of D-glucose are a-D-
glucopyranose and b-D-
glucopyranose.
Formation of the two cyclic forms of D-glucose.
Solution of a-anomer of glucose
rotates the plane of polarized light to
right (10% solution at 20°C +112 °).
For the b-anomer, this value: +18.7°
If freshly prepared a-D-glucose
solution is monitored , it is observed
that the optical activity
decreases and finally reaches +52.7°.
The reason of that is
conversion of some of the
a-D- glucose to b-D-glucose.
This rotation is called
mutarotation.

Mutarotation
 Mutarotation

a-D-Glucopyranose D-Glucopyranose β-D-Glucopyranose

In solution, D-Glucose exists as intra-molecular hemiasetal.
Mutarotation causes the formation of an equilibrium mixture
consisting of 63.6% of the β anomer and 36.4% of the a anomer
(open chain form 0.02%).
Enzymes use only one of these forms or derivatives. Mutarotase
enzyme catalyzes the convertion between them.
Pyranoses and furanoses
Conformational formulas of pyranoses
Monosaccharide Derivatives
In addition to simple hexoses, there are a number of sugar
derivatives in which a hydroxyl group in the parent compound
is replaced with another substituent, or a carbon atom is
oxidized to a carboxyl group.
Phosphorylated Sugars
Monosaccharide Derivatives
Amino Sugars
In glucosamine, galactosamine, and mannosamine, the hydroxyl at
C-2 of the parent compound is replaced with an amino group.

The amino group is nearly always condensed with acetic acid, as in
N-acetylglucosamine. This glucosamine derivative is part of many
structural polymers, including those of the bacterial cell wall.
Monosaccharide Derivatives
Bacterial cell
walls also
contain a
derivative of
glucosamine,
N-acetyl-
muramic acid, in
which lactic acid
(a three-carbon
carboxylic acid)
is ether-linked to
the oxygen at C-
3 of N-acetyl-
glucosamine.
Monosaccharide Derivatives
Deoxy Sugars
The substitution of a hydrogen for the group at C-6 of
L-galactose or L-mannose produces L-fucose or L-rhamnose,
respectively; these deoxy sugars are found in plant
polysaccharides and in the complex oligosaccharide
components of glycoproteins and glycolipids.
 Aldonic Acids and Uronic Acids
Oxidation of the carbonyl (aldehyde) carbon of glucose to
the carboxyl level produces gluconic acid; other aldoses
yield other aldonic acids.
Oxidation of the carbon at the other end of the carbon
chain—C-6 of glucose, galactose, or mannose—forms the
corresponding uronic acid: glucuronic, galacturonic, or
mannuronic acid. Both aldonic and uronic acids form
stable intramolecular esters called lactones.
 SUGAR ACIDS
SUGAR ALDONIC A. URONIC A. ALDARIC A.
Glucose Gluconic Glucuronic Glucaric
Galactose Galactonic Galacturonic Galactaric
 Aldonic Acids and Uronic Acids
In addition to acidic hexose derivatives, there is a nine-carbon
acidic sugar derivative called N-acetylneuraminic acid (sialic
acid).
This is a derivative of N-acetylmannosamine, and is a com-
ponent of many glycoproteins and glycolipids in animals.
The carboxylic acid groups of the acidic sugar derivatives are
ionized at pH 7. Therefore they carry net negative charge.
Reduced Sugars (Poliols)
Reduced Sugars
Dihydroxyacetone, Glyceraldehyde Glycerol
Glucose, Fructose Sorbitol
Mannose Mannitol
Galactose Galactitol
Xylose Xylitol

Alcohol
derivatives of
monosaccharides
are formed by the
reduction of
carbonyl group.
Sugars as reducing agents