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Glycoside
Glycoside
Glycoside
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Salicin, a glycoside related to aspirin
Chemical structure of oleandrin, a cardiac glycoside

In chemistry, a glycoside /ˈɡlkəsd/ is a molecule in which a sugar is bound to another functional group via a glycosidic bond. Glycosides play numerous important roles in living organisms. Many plants store chemicals in the form of inactive glycosides. These can be activated by enzyme hydrolysis,[1] which causes the sugar part to be broken off, making the chemical available for use. Many such plant glycosides are used as medications. Several species of Heliconius butterfly are capable of incorporating these plant compounds as a form of chemical defense against predators.[2] In animals and humans, poisons are often bound to sugar molecules as part of their elimination from the body.

In formal terms, a glycoside is any molecule in which a sugar group is bonded through its anomeric carbon to another group via a glycosidic bond. Glycosides can be linked by an O- (an O-glycoside), N- (a glycosylamine), S-(a thioglycoside), or C- (a C-glycoside) glycosidic bond. According to the IUPAC, the name "C-glycoside" is a misnomer; the preferred term is "C-glycosyl compound".[3] The given definition is the one used by IUPAC, which recommends the Haworth projection to correctly assign stereochemical configurations.[4]

Many authors require in addition that the sugar be bonded to a non-sugar for the molecule to qualify as a glycoside, thus excluding polysaccharides. The sugar group is then known as the glycone and the non-sugar group as the aglycone or genin part of the glycoside. The glycone can consist of a single sugar group (monosaccharide), two sugar groups (disaccharide), or several sugar groups (oligosaccharide).

The first glycoside ever identified was amygdalin, by the French chemists Pierre Robiquet and Antoine Boutron-Charlard, in 1830.[5]

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Molecules containing an N-glycosidic bond are known as glycosylamines. Many authors in biochemistry call these compounds N-glycosides and group them with the glycosides; this is considered a misnomer and is discouraged by the International Union of Pure and Applied Chemistry. Glycosylamines and glycosides are grouped together as glycoconjugates; other glycoconjugates include glycoproteins, glycopeptides, peptidoglycans, glycolipids, and lipopolysaccharides.[citation needed]

Chemistry

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Much of the chemistry of glycosides is explained in the article on glycosidic bonds. For example, the glycone and aglycone portions can be chemically separated by hydrolysis in the presence of acid and can be hydrolyzed by alkali. There are also numerous enzymes that can form and break glycosidic bonds. The most important cleavage enzymes are the glycoside hydrolases, and the most important synthetic enzymes in nature are glycosyltransferases. Genetically altered enzymes termed glycosynthases have been developed that can form glycosidic bonds in excellent yield.[citation needed]

There are many ways to chemically synthesize glycosidic bonds. Fischer glycosidation refers to the synthesis of glycosides by the reaction of unprotected monosaccharides with alcohols (usually as solvent) in the presence of a strong acid catalyst. The Koenigs-Knorr reaction is the condensation of glycosyl halides and alcohols in the presence of metal salts such as silver carbonate or mercuric oxide.[citation needed]

Classification

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Glycosides can be classified by the glycone, by the type of glycosidic bond, and by the aglycone.

By glycone/presence of sugar

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If the glycone group of a glycoside is glucose, then the molecule is a glucoside; if it is fructose, then the molecule is a fructoside; if it is glucuronic acid, then the molecule is a glucuronide; etc. In the body, toxic substances are often bonded to glucuronic acid to increase their water solubility; the resulting glucuronides are then excreted. Compounds can also be generally defined based on the class of glycone; for example, biosides are glycosides with a disaccharide (biose) glycone.

By type of glycosidic bond

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Depending on whether the glycosidic bond lies "below" or "above" the plane of the cyclic sugar molecule, glycosides are classified as α-glycosides or β-glycosides. Some enzymes such as α-amylase can only hydrolyze α-linkages; others, such as emulsin, can only affect β-linkages.

There are four type of linkages present between glycone and aglycone:

  • C-linkage/glycosidic bond, "nonhydrolysable by acids or enzymes"
  • O-linkage/glycosidic bond
  • N-linkage/glycosidic bond
  • S-linkage/glycosidic bond

By aglycone

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Glycosides are also classified according to the chemical nature of the aglycone. For purposes of biochemistry and pharmacology, this is the most useful classification.

Alcoholic glycosides

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An example of an alcoholic glycoside is salicin, which is found in the genus Salix. Salicin is converted in the body into salicylic acid, which is closely related to aspirin and has analgesic, antipyretic, and anti-inflammatory effects.

Anthraquinone glycosides

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These glycosides contain an aglycone group that is a derivative of anthraquinone. They have a laxative effect. They are mainly found in dicot plants except the family Liliaceae which are monocots. They are present in senna, rhubarb and Aloe species. Anthron and anthranol are reduced forms of anthraquinone.

Coumarin glycosides

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Here, the aglycone is coumarin or a derivative. An example is apterin which is reported to dilate the coronary arteries as well as block calcium channels. Other coumarin glycosides are obtained from dried leaves of Psoralea corylifolia.

Chromone glycosides

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In this case, the aglycone is called benzo-gamma-pyrone.

Cyanogenic glycosides

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Amygdalin

In this case, the aglycone contains a cyanohydrin group. Plants that make cyanogenic glycosides store them in the vacuole, but, if the plant is attacked, they are released and become activated by enzymes in the cytoplasm. These remove the sugar part of the molecule, allowing the cyanohydrin structure to collapse and release toxic hydrogen cyanide. Storing them in inactive forms in the vacuole prevents them from damaging the plant under normal conditions.[6]

Along with playing a role in deterring herbivores, in some plants they control germination, bud formation, carbon and nitrogen transport, and possibly act as antioxidants.[6] The production of cyanogenic glycosides is an evolutionarily conserved function, appearing in species as old as ferns and as recent as angiosperms.[6] These compounds are made by around 3,000 species. In screens they are found in about 11% of cultivated plants but only 5% of plants overall; humans seem to have selected for them.[6]

Examples include amygdalin and prunasin which are made by the bitter almond tree; other species that produce cyanogenic glycosides are sorghum (from which dhurrin, the first cyanogenic glycoside to be identified, was first isolated), barley, flax, white clover, and cassava, which produces linamarin and lotaustralin.[6]

Amygdalin and a synthetic derivative, laetrile, were investigated as potential drugs to treat cancer and were heavily promoted as alternative medicine; they are ineffective and dangerous.[7]

Some butterfly species, such as the Dryas iulia and Parnassius smintheus, have evolved to use the cyanogenic glycosides found in their host plants as a form of protection against predators through their unpalatability.[8][9]

Flavonoid glycosides

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Here, the aglycone is a flavonoid. Examples of this large group of glycosides include:

Among the important effects of flavonoids are their antioxidant effect. They are also known to decrease capillary fragility.

Phenolic glycosides

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Here, the aglycone is a simple phenolic structure. An example is arbutin found in the Common Bearberry Arctostaphylos uva-ursi. It has a urinary antiseptic effect.

Saponins

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Main article: Saponin

These compounds give a permanent froth when shaken with water. They also cause hemolysis of red blood cells. Saponin glycosides are found in liquorice. Their medicinal value is due to their expectorant, corticoid and anti-inflammatory effects. Steroid saponins are important starting material for the production of semi-synthetic glucocorticoids and other steroid hormones such as progesterone; for example in Dioscorea wild yam the sapogenin diosgenin, in the form of its glycoside dioscin. The ginsenosides are triterpene glycosides and ginseng saponins from Panax ginseng (Chinese ginseng) and Panax quinquefolius (American ginseng). In general, the use of the term saponin in organic chemistry is discouraged, because many plant constituents can produce foam, and many triterpene-glycosides are amphipolar under certain conditions, acting as a surfactant. More modern uses of saponins in biotechnology are as adjuvants in vaccines: Quil A and its derivative QS-21, isolated from the bark of Quillaja saponaria Molina, to stimulate both the Th1 immune response and the production of cytotoxic T-lymphocytes (CTLs) against exogenous antigens make them ideal for use in subunit vaccines and vaccines directed against intracellular pathogens as well as for therapeutic cancer vaccines but with the aforementioned side-effect of hemolysis.[10] Saponins are also natural ruminal antiprotozoal agents that are potential to improve ruminal microbial fermentation reducing ammonia concentrations and methane production in ruminant animals.[11]

Steroid glycosides (cardiac glycosides)

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Main article: Cardiac glycoside

In these glycosides, the aglycone part is a steroid nucleus. These glycosides are found in the plant genera Digitalis, Scilla, and Strophanthus. They are used in the treatment of heart diseases, e.g., congestive heart failure (historically as now recognised does not improve survivability; other agents[example needed] are now preferred[medical citation needed]) and arrhythmia.

Steviol glycosides

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Main article: Steviol glycoside

These sweet glycosides found in the stevia plant Stevia rebaudiana Bertoni have 40–300 times the sweetness of sucrose. The two primary glycosides, stevioside and rebaudioside A, are used as natural sweeteners in many countries. These glycosides have steviol as the aglycone part. Glucose or rhamnose-glucose combinations are bound to the ends of the aglycone to form the different compounds.

Iridoid glycosides

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These contain an iridoid group; e.g. aucubin, geniposidic acid, theviridoside, loganin, catalpol.

Thioglycosides

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As the name contains the prefix thio-, these compounds contain sulfur. Examples include sinigrin, found in black mustard, and sinalbin, found in white mustard.

See also

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References

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Glycoside

View on Grokipedia
from Grokipedia
A glycoside is a in which one or more groups, known as the glycone, are covalently attached to a non-sugar moiety, called the aglycone, via a typically formed at the anomeric carbon of the sugar. These compounds are non-reducing derivatives of carbohydrates, as the glycosidic linkage prevents the sugar from exhibiting typical reducing properties or anomerization in aqueous solutions. Glycosides are named based on the sugar component, such as glucosides for those containing glucose. Glycosides are ubiquitous in , occurring primarily as secondary metabolites in , where they play crucial roles in defense mechanisms against herbivores and pathogens by releasing toxic aglycones upon enzymatic . They are also present in animals, microorganisms, and some marine organisms, contributing to processes like molecular recognition, signaling, and . In , glycosides often accumulate in specific tissues such as seeds, bark, and leaves, with examples including in bitter almonds and in willow bark. Glycosides are classified by their aglycone structure or biological activity, encompassing diverse types such as cardiac glycosides (steroid-based compounds like from foxglove, used therapeutically for due to their inhibition of Na+/K+-ATPase), cyanogenic glycosides ( derivatives that liberate for ), anthraquinone glycosides (found in laxative plants like senna), and saponin glycosides ( or derivatives with amphiphilic properties). Biosynthesis typically involves glycosyltransferases that link activated sugar donors, such as UDP-glucose, to the aglycone, while hydrolysis by glycosidases activates or detoxifies them . Pharmacologically, glycosides exhibit a wide range of effects, from cardiotonic and anticancer activities to toxicity, underscoring their significance in , , and .

Fundamentals

Definition

A glycoside is any compound containing a moiety (glycone) that, upon , yields one or more s and a non- moiety (aglycone) bound together by a glycosidic linkage. This linkage typically involves the anomeric carbon of the and a hydroxyl group (or occasionally another nucleophilic group) on the aglycone, forming a mixed derivative of the . Glycosides were first systematically isolated and studied in the from plant extracts, with —obtained from willow bark (Salix spp.)—representing a pivotal early example isolated in 1828 by German chemist Johann Andreas Buchner. This discovery marked the beginning of recognizing glycosides as distinct natural products with potential pharmacological value, distinct from simple carbohydrates. In contrast to free sugars, which exist primarily as hemiacetals and possess reducing properties due to their free anomeric hydroxyl group, glycosides are non-reducing because the anomeric carbon is engaged in the stable acetal-like ; reducing character emerges only upon of this bond. The general formula for a typical O-glycoside is R–O–, where R denotes the aglycone and the sugar is attached via its anomeric oxygen.

Components and General Structure

Glycosides are composed of two primary components: a glycone, which is the portion, and an aglycone, the non- portion, connected through a glycosidic linkage. The glycone is typically a such as glucose or , but it can also consist of oligosaccharides ranging from disaccharides to more complex chains. This sugar component exists in either the alpha (α) or beta (β) anomeric form, determined by the configuration at the anomeric carbon (C1 in aldoses or C2 in ketoses), which influences the orientation of the hydroxyl group relative to the ring plane in the cyclic structure. The aglycone, also known as the genin in certain contexts like steroidal glycosides, is a diverse non-sugar moiety that can include alcohols (e.g., in ethyl glucoside), phenols (e.g., in from willow bark), flavonoids (e.g., in various plant glycosides), or steroids (e.g., digitoxigenin in cardiac glycosides). In steroidal glycosides, the aglycone is specifically termed a genin, referring to the core nucleus after removal of the sugar moiety, as seen in compounds like ouabagenin. The overall structure of glycosides centers on the linking the glycone and aglycone, with O-glycosides being the most prevalent form, represented simply as Aglycone–O–, where the oxygen atom bridges the anomeric carbon of the sugar to a hydroxyl group on the aglycone. Variants include C-glycosides (Aglycone–C–), which feature a direct carbon-carbon bond and exhibit greater resistance to , and S-glycosides (Aglycone–S–), involving a linkage as found in glucosinolates. The at the anomeric carbon, distinguishing α- and β-glycosides, plays a critical role in the physical, chemical, and biological properties of glycosides, including , stability, enzymatic recognition, and bioactivity, as α-anomers often differ in and receptor interactions compared to β-anomers. For instance, β-configurations are commonly associated with higher water and specific interactions in natural systems, while α-forms may enhance permeability.

Chemistry

Glycosidic Bond

The glycosidic bond is a covalent linkage formed between the anomeric carbon of a moiety (glycone) and a nucleophilic group on another (aglycone), typically involving the elimination of from a and a hydroxyl, , , or carbon . This bond connects the reducing end of the to the aglycone, rendering the anomeric carbon non-reducing and preventing . In chemical terms, it represents the product of a cyclic with a , resulting in a stable ether-like connection at the anomeric position. Glycosidic bonds are classified by the atom linking the anomeric carbon to the aglycone. The most prevalent are O-glycosides, where the bond forms through an oxygen atom from a hydroxyl group on the aglycone, as seen in common disaccharides and many plant metabolites. C-glycosides involve a direct carbon-carbon bond, offering greater resistance to due to the absence of a labile ; notable examples include in species. N-glycosides link via a nitrogen atom, commonly found in nucleosides where the sugar attaches to or bases. S-glycosides, less frequent, connect through , as in glucosinolates ( glucosides) from cruciferous . Electronically, the glycosidic bond exhibits characteristics of an acetal, with the anomeric carbon bonded to two oxygen atoms in O-glycosides—one from the sugar ring and one exocyclic—represented generally as the structure where the anomeric carbon (C1) is part of Ring-O-CH(OR’)- (rest of sugar ring),\text{Ring-O-CH(OR')- (rest of sugar ring)}, with R' being the aglycone substituent. Resonance between the ring oxygen lone pair and the anomeric carbon imparts partial double-bond character to the endocyclic C-O bond, contributing to conformational rigidity and the anomeric effect that stabilizes axial substituents in certain configurations. This resonance stabilization distinguishes glycosidic acetals from simple dialkyl acetals, influencing their reactivity and stereochemistry.

Formation and Hydrolysis

Glycosides are formed through the establishment of a between a moiety (glycone) and an aglycone, typically via dehydration or activation strategies in or direct transfer in enzymatic processes. In laboratory settings, one of the earliest and simplest methods is the Fischer glycosylation, developed by in the late 19th century, which involves the acid-catalyzed reaction of a free (as a ) with an alcohol under equilibrating conditions to yield the corresponding glycoside. This reversible process proceeds through protonation of the anomeric hydroxyl group, loss of to form an oxocarbenium intermediate, and subsequent nucleophilic attack by the alcohol, often favoring the thermodynamically stable due to the . A representative for this reaction is: R-CH(OH)-OR’+H+R-CH(OR’)-OH2+R-CH(OR’)-O-R”+H2O\text{R-CH(OH)-OR'} + \text{H}^+ \rightleftharpoons \text{R-CH(OR')-OH}_2^+ \rightarrow \text{R-CH(OR')-O-R''} + \text{H}_2\text{O} where R represents the sugar ring and R'' the aglycone alcohol. For more controlled stereoselectivity, particularly in complex syntheses, the Koenigs-Knorr method, introduced in 1901, employs activated glycosyl halides (such as bromides or chlorides) derived from peracetylated sugars, reacted with an aglycone alcohol in the presence of promoters like silver carbonate or silver oxide. The halide serves as a leaving group, generating an oxocarbenium ion that is trapped by the alcohol nucleophile, with neighboring group participation from a C-2 acetoxy substituent often directing β-selectivity in pyranosides. This method has been refined over decades to include modern variants using silver triflate or other Lewis acids for improved yields in oligosaccharide assembly. Enzymatically, glycosides are synthesized in vivo and in vitro by glycosyltransferases (GTs, EC 2.4), which catalyze the stereospecific transfer of a unit from an activated donor, such as (UDP-Glc), to an acceptor aglycone bearing a hydroxyl, , , or even carbon . These enzymes, numbering over 300,000 sequences across 139 CAZy families (as of October 2025), operate via either inverting (SN2-like, single displacement) or retaining (double displacement or SNi-like) mechanisms, with the former using a catalytic base to deprotonate the acceptor and the latter forming a transient covalent glycosyl-enzyme intermediate. For example, UGT78G1 transfers glucose from UDP-Glc to , yielding O-linked glycosides with high regio- and under mild aqueous conditions. The general reaction scheme is: UDP-Glc+HO-RGTGlc-O-R+UDP\text{UDP-Glc} + \text{HO-R} \xrightarrow{\text{GT}} \text{Glc-O-R} + \text{UDP}
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