Glycosylation

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Glycosylation (see also chemical glycosylation) is the reaction in which a carbohydrate, i.e. a glycosyl donor, is attached to a hydroxyl or other functional group of another molecule (a glycosyl acceptor). In biology glycosylation mainly refers in particular to the enzymatic process that attaches glycans to proteins, lipids, or other organic molecules. This enzymatic process produces one of the fundamental biopolymers found in cells (along with DNA, RNA, and proteins). Glycosylation is a form of co-translational and post-translational modification. Glycans serve a variety of structural and functional roles in membrane and secreted proteins.^[1] The majority of proteins synthesized in the rough ER undergo glycosylation. It is an enzyme-directed site-specific process, as opposed to the non-enzymatic chemical reaction of glycation. Glycosylation is also present in the cytoplasm and nucleus as the O-GlcNAc modification. Five classes of glycans are produced:

N-linked glycans attached to a nitrogen of asparagine or arginine side-chains. N-linked glycosylation requires participation of a special lipid called dolichol phosphate.
O-linked glycans attached to the hydroxy oxygen of serine, threonine, tyrosine, hydroxylysine, or hydroxyproline side-chains, or to oxygens on lipids such as ceramide
phospho-glycans linked through the phosphate of a phospho-serine;
C-linked glycans, a rare form of glycosylation where a sugar is added to a carbon on a tryptophan side-chain
glypiation, which is the addition of a GPI anchor that links proteins to lipids through glycan linkages.

Purpose

The carbohydrate chains attached to the target proteins serve various functions.^[2] For instance, some proteins do not fold correctly unless they are glycosylated first.^[1] Also, polysaccharides linked at the amide nitrogen of asparagine in the protein confer stability on some secreted glycoproteins. Experiments have shown that glycosylation in this case is not a strict requirement for proper folding, but the unglycosylated protein degrades quickly. Glycosylation also plays a role in cell-cell adhesion (a mechanism employed by cells of the immune system) via sugar-binding proteins called lectins, which recognize specific carbohydrate moieties.^[1]

Glycoprotein Diversity

Glycosylation increases diversity in the proteome, because almost every aspect of glycosylation can be modified, including:

Glycosidic bond — the site of glycan linkage
Glycan composition — the types of sugars that are linked to a given protein
Glycan structure — can be unbranched or branched chains of sugars
Glycan length — can be short- or long-chain oligosaccharides

Mechanisms

There are various mechanisms for glycosylation, although most share several common features:^[1]

Glycosylation, unlike glycation, is an enzymatic process. Indeed, glycosylation is thought to be the most complex post-translational modification, because of the large number of enzymatic steps involved.^[3]
The donor molecule is often an activated nucleotide sugar
The process is non-templated (unlike DNA transcription or protein translation); instead, the cell relies on segregating enzymes into different cellular compartments (e.g., endoplasmic reticulum, cisternae in Golgi apparatus). Therefore, glycosylation is a site-specific modification.

Types of glycosylation

N-linked glycosylation

Main article: N-linked glycosylation

N-linked glycosylation is the most common type of glycosidic bond and is important for the folding of some eukaryotic proteins and for cell-cell and cell-extracellular matrix attachment. The N-linked glycosylation process occurs in eukaryotes in the lumen of the endoplasmic reticulum and widely in archaea, but very rarely in bacteria.

O-linked glycosylation

Main article: O-linked glycosylation

O-linked glycosylation is a form of glycosylation that occurs in eukaryotes in the Golgi apparatus,^[4] but also occurs in archaea and bacteria.

Phospho-serine glycosylation

Xylose, fucose, mannose, and GlcNAc phospho-serine glycans have been reported in the literature. Fucose and GlcNAc have been found only in Dictyostelium discoideum, mannose in Leishmania mexicana, and xylose in Trypanosoma cruzi. Mannose has recently been reported in a vertebrate, the mouse, Mus musculus, on the cell-surface laminin receptor alpha dystroglycan⁴. It has been suggested this rare finding may be linked to the fact that alpha dystroglycan is highly conserved from lower vertebrates to mammals.^[5]

C-mannosylation

A mannose sugar is added to the first tryptophan residue in the sequence W-X-X-W (W indicates tryptophan; X is any amino acid). Thrombospondins are one of the most commonly C-modified proteins, although this form of glycosylation appears elsewhere as well. C-mannosylation is unusual because the sugar is linked to a carbon rather than a reactive atom such as nitrogen or oxygen. Recently, the first crystal structure of a protein containing this type of glycosylation has been determined - that of human complement component 8, PDB ID 3OJY.

Formation of GPI anchors (glypiation)

A special form of glycosylation is the formation of a GPI anchor. In this kind of glycosylation a protein is attached to a lipid anchor, via a glycan chain. (See also prenylation.)

Clinical

Over 40 disorders of glycosylation have been reported in humans.^[6] These can be divided into four groups: disorders of protein N-glycosylation, disorders of protein O-glycosylation, disorders of lipid glycosylation and disorders of other glycosylation pathways and of multiple glycosylation pathways. No effective treatment is known for any of these disorders. 80% of these affect the nervous system.

References

↑ 1.0 1.1 1.2 1.3 edited by Ajit Varki ... (2009). Essentials of Glycobiology. Ajit Varki (ed.) (2nd ed.). Cold Spring Harbor Laboratories Press. ISBN 978-0-87969-770-9.
↑ Drickamer, K; M.E. Taylor (2006). Introduction to Glycobiology (2nd ed.). Oxford University Press, USA. ISBN 978-0-19-928278-4. Cite uses deprecated parameters (help)
↑ Walsh, Christopher (2006). Posttranslational modification of proteins: Expanding nature's inventory. Roberts and Co. Publishers, Englewood, CO. ISBN 0974707732.
↑ William G. Flynne (2008). Biotechnology and Bioengineering. Nova Publishers. pp. 45–. ISBN 978-1-60456-067-1. Retrieved 13 November 2010.
↑ Yoshida-Moriguchi, T., et al (2010). Science. 327(5961):88-92.
↑ Jaeken J (2013) Congenital disorders of glycosylation. Handb Clin Neurol. 2013;113:1737-43. doi: 10.1016/B978-0-444-59565-2.00044-7

External links

GlycoEP : In silico Platform for Prediction of N-, O- and C-Glycosites in Eukaryotic Protein Sequences PLoS ONE 8(6): e67008
Online textbook of glycobiology with chapters about glycosylation
GlyProt: In-silico N-glycosylation of proteins on the web
NetNGlyc: The NetNglyc server predicts N-glycosylation sites in human proteins using artificial neural networks that examine the sequence context of Asn-Xaa-Ser/Thr sequons.
Supplementary Material of the Book "The Sugar Code"
Additional information on glycosylation and figures

Protein primary structure and posttranslational modifications

General

N terminus

C terminus

Single specific AAs

Serine/Threonine	Phosphorylation Dephosphorylation Glycosylation Methylidene-imidazolone (MIO) formation

Tyrosine	Phosphorylation Dephosphorylation Sulfation Porphyrin ring linkage Adenylylation Flavin linkage Topaquinone (TPQ) formation Detyrosination

Cysteine	Palmitoylation Prenylation

Aspartate	Succinimide formation

Glutamate	Carboxylation Methylation Polyglutamylation Polyglycylation

Asparagine	Deamidation Glycosylation

Glutamine	Transglutamination

Lysine	Methylation Acetylation Acylation Adenylylation Hydroxylation Ubiquitination Sumoylation ADP-ribosylation Deamination Oxidative deamination to aldehyde O-glycosylation Imine formation Glycation Carbamylation

Arginine	Citrullination Methylation ADP-ribosylation

Proline	Hydroxylation

Histidine	Diphthamide formation Adenylylation

Tryptophan	C-mannosylation

Crosslinks between two AAs

Cysteine-Cysteine	Disulfide bond

Methionine-Hydroxylysine	Sulfilimine bond

Lysine-Tyrosylquinone	Lysine tyrosylquinone (LTQ) formation

Tryptophan-Tryptophylquinone	Tryptophan tryptophylquinone (TTQ) formation

Three consecutive AAs
(chromophore formation)

Serine–Tyrosine–Glycine	p-Hydroxybenzylidene-imidazolinone formation

Histidine–Tyrosine–Glycine	4-(p-hydroxybenzylidene)-5-imidazolinone formation

Crosslinks between four AAs

Allysine-Allysine-Allysine-Lysine	Desmosine

←Amino acids

Secondary structure→

Metabolism (Catabolism, Anabolism)

General

Energy
metabolism

Aerobic respiration	Glycolysis → Pyruvate Decarboxylation → Citric acid cycle → Oxidative phosphorylation (Electron Transport Chain + ATP synthase)

Anaerobic respiration	Electron acceptors are other than oxygen

Fermentation	Glycolysis → Substrate-level phosphorylation ABE Ethanol Lactic acid

Specific
paths

Protein metabolism

Carbohydrate metabolism
(Carbohydrate catabolism
and anabolism)

Human

Glycolysis ⇄ Gluconeogenesis

Glycogenolysis ⇄ Glycogenesis

Pentose phosphate pathway Fructolysis Galactolysis

Glycosylation N-linked O-linked

Nonhuman

Photosynthesis Anoxygenic photosynthesis Chemosynthesis Carbon fixation

Xylose metabolism

Lipid metabolism
(Lipolysis, Lipogenesis)

Fatty acid metabolism	Fatty acid degradation (Beta oxidation) Fatty acid synthesis

Other	Steroid metabolism Sphingolipid metabolism Eicosanoid metabolism Ketosis

Amino acid

Nucleotide
metabolism

Other

M: MET

mt, k, c/g/r/p/y/i, f/h/s/l/o/e, a/u, n, m

k, cgrp/y/i, f/h/s/l/o/e, au, n, m, epon

m (A16/C10), i (k, c/g/r/p/y/i, f/h/s/o/e, a/u, n, m)

Biochemical families: carbohydrates
- alcohols
- glycoproteins
- glycosides
lipids
- eicosanoids
- fatty acids / intermediates
- phospholipids
- sphingolipids
- steroids
nucleic acids
- constituents / intermediates
proteins
- Amino acids / intermediates
tetrapyrroles / intermediates

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