Glycosides Introduction PDF

Summary

This document provides an introduction to glycosides, focusing on their chemical structures, classifications, and biological roles. It discusses different types of glycosides based on linkage type and chemical nature. The text explains properties like solubility and stability.

Full Transcript

Glycosides
Glycoside: is an organic compound, usually of plant
origin, that is composed of a sugar portion linked to a
non-sugar moiety by glycosidic bond.

The sugar portion is called glycon,
The non-sugar portion is called aglycon or genin;
In general there are four basic classes of glycosides:C-
glycosides, in which the sugar is attached to the
aglycone through C-C bond, and the O- glycosides in
which the sugar is connected to the aglycone through
oxygen –carbon bond,S-glycosides and N-glycosides.
 therefore glycosides yield one or more sugars among
the products upon enzymatic or acid hydrolysis.
The sugar component of glycosides may be mono, di, tri
or tetrasaccharides.
 Alpha and Beta glycosides
Sugars in glycosides exist in isomeric α and β forms so both α and β
glycosides are theoretically possible. but the β-form is the one that
occur in plants
The two diastereoisomers differ in configuration about the anomeric
carbon (C-1) can exist α and β.
If the hydroxyl group on the anomeric carbon is down in relation to
the cyclic structure, it is α anomer while if the hydroxyl group on the
anomeric carbon is up in relation to the cyclic structure, it is β
anomer.
 Chemically the glycosides are acetals in which the hydroxyl
group (OH) of the glycone is condensed with the hydroxyl group
of aglycone.
Sugars exist predominantly as cyclic hemiacetals (R-O-C-OH
group), while glycosides are usually mixed acetals (R-O-C-O-R)
group.
 Inside the body the glycosides will be cleaved
to glycone and aglycone parts,
the glycone part confers on the molecule
solubility properties, thus is important in the
absorption and distribution in the body,
while the aglycone part is responsible for the
pharmacological activity.
Physical and chemical properties of glycosides

Because of the complexity of the structure of the
naturally occurring glycosides, no generalization are
possible with regard to their stability.
In addition there are differences in their solubility
properties.
 1. Solubility:
Most glycosides are soluble in water or
hydroalcoholic solutions and insoluble or less soluble
in non-polar organic solvents, because the solubility
properties of the sugar residues exert a considerable
effect i.e. sugar moiety increases water solubility.
The aglycon part is soluble in non-polar (organic)
solvents like
benzene, ether and chloroform.
 2. Stability and hydrolytic cleavage:
A. Acids and alkali: Glycosides can be hydrolyzed by
heating with a dilute acid where by the glycosidic
linkages are cleaved, while glycosides are relatively
stable towards alkalis.
Glycosides can be hydrolyzed by heating with a dilute
acid where by the glycosidic linkages are cleaved.

Glycosides can be also hydrolyzed by appropriate
enzymes, which are usually found in the same plant, in
separate compartments.
There is a specific enzyme for each glycosides to exert
a hydrolytic action on it.
 B. Enzyme hydrolysis:
Enzymatic hydrolysis: there is a specific enzyme that exerts a
hydrolytic action on it.
Glycosides can be hydrolyzed by appropriate enzymes, which
are usually found in the same plant, in separate compartments.
The same enzyme is capable to hydrolyze different glycosides,
but α and β stereo-isomers of the same glycoside are usually
not hydrolyzed by the same enzyme.
Emulsin is found to hydrolyzed most β-glycoside linkages while
maltase and invertase are α-glycosidases, capable of
hydrolyzing
3. Shape, color, taste and odor
A. Shape: Glycosides are solid, amorphous and non volatile.
B. Color: Glycosides are colourless except flavonoids are
yellow and anthraquinones are red or orange.
C. Taste: Most of glycosides are bitter taste.
D. Odor: Glycosides are odorless except saponin (glycyrrhizin)
Importance of Glycosides
1. Glycosides play an important role in the life of the
plant and are involved in different functions. It serve as:
A. As sugar reserves
B. As waste products of plant metabolism
C. As a mean of detoxification
D. To regulate osmosis
E. To regulate the supply of substances of importance in
metabolism
F. Has a role of defense against the invasion to the tissues
by microorganism some pointed out that aglycones are
antiseptics and hence are bactericidal in nature
 2. Many therapeutic agents are derived from glycosides. In
fact, the group contributes to almost every therapeutic class.
A. Some of our most valuable cardiac glycosides from digitalis,
strophanthus, squill and others.
B. Laxative drugs, such as senna, aloe, rhubarb, cascara
sagrada, and frangula, contain emodin and other
anthraquinone glycosides;
C. Sinigrin, a glycoside from black mustard, yields allyl
isothiocyanate, a powerful local irritant.
Classification of glycosides

1- According to the type of glycosidic
linkage:
α-glycosides (α sugar)
β-glycosides (β sugar)
2- according to the chemical group of the aglycon
involved in the formation of glycoside linkage.

Aglycone- O- Sugar O-glycosides(OH group): eg.
Senna and rhubarb
Aglycone- C- Sugar C-glycosides (C- group): eg.
Cascaroside from cascara
Aglycone- S- Sugar S-glycosides (SH- group):
eg. sinigrin from black mustard
Aglycone-N-Sugar: N-glycosides(NH-group):
eg. glycoalkaloid.
3- According to the chemical nature of the aglycon, the
glycosides containing drugs can be classified into:

Cardioactive group.
Anthraquinone group.
Saponin group.
Cyanophore group.
Isothiocyanate group.
Flavonol group.
Alcohol group.
Aldehyde group.
Phenol group
4- According to the nature of the simple sugar
component of the glycoside:

1- Glucoside (the glycone is glucose).
2- Galactoside (the glycone is galactose).
3- Mannoside (the glycone is mannose).
4- Arabinoside (the glycone is arabinose).
Biosynthesis of glycosides
The biosynthetic pathways are widely variable
depending on the type of aglycone as well as the
glycone units.
The aglycone and the sugar parts are biosynthesized
separately, and then coupled to form a glycoside.
The coupling of the two parts occurs via
phosphorylation of a sugar to yields a sugar 1-
phosphate which reacts with a uridine triphosphate
to form a uridine diphosphate sugar (UDP-sugar) and
inorganic phosphate.
This UDP-sugar reacts with the aglycone to form the
glycoside and a free UDP
sugar phosphorylation sugar-1-P

UTP + sugar-1-P UDP – sugar + Ppi

UDP – sugar + aglycone sugar – aglycone + UDP
(glycoside)
Extraction of glycosides

Since glycosides are accompanied by specific
hydrolyzing enzymes, these enzymes must be
inactivated by putting the plant in boiling water or
alcohol.
Defatting or purification of the plant material in case
of seeds.
1. Defatting or purification of the plant material in
case of seeds.
2. Treatment with lead acetate to precipitate tannins
and other non glycosidal impurities.
3. Removal of any excess of lead acetate by passing
hydrogen sulfide H2S gas through the solution.
4. The extract is filtered and concentrated to get crude
glycoside.
5. Purification of the crude glycosides by
chromatography or crystallization.