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{{DISPLAYTITLE:''O''-linked glycosylation}}
{{DISPLAYTITLE:''O''-linked glycosylation}}
'''''O''-linked glycosylation''' is the attachment of a [[sugar]] molecule to the [[oxygen]] atom of serine (Ser) or threonine (Thr) residues in a protein. '''''O''-glycosylation''' is a [[post-translational modification]] that occurs after the protein has been synthesised. In [[eukaryote]]s, it occurs in the [[endoplasmic reticulum]], [[Golgi apparatus]] and occasionally in the [[cytoplasm]]; in [[prokaryote]]s, it occurs in the cytoplasm.<ref name="Steen 1998">{{cite journal |last1=Van den Steen |first1=Philippe |last2=M. Rudd |first2=Pauline |last3=A. Dwek |first3=Raymond |last4=Opdenakker |first4=Ghislain |title=Concepts and Principles of O-Linked Glycosylation |journal=Critical Reviews in Biochemistry and Molecular Biology |date=1998 |volume=33 |issue=3 |pages=151–208 |doi=10.1080/10409239891204198}}</ref> Several different sugars can be added to the serine or threonine, and they affect the protein in different ways by changing protein stability and regulating protein activity. ''O''-glycans, which are the sugars added to the serine or threonine, have numerous functions throughout the body, including trafficking of cells in the immune system, allowing recognition of foreign material, controlling cell [[metabolism]] and providing cartilage and tendon flexibility.<ref name="Hounsell 1995">{{cite journal |last1=F. Hounsell |first1=Elizabeth |last2=J. Davies |first2=Michael |last3=V. Renouf |first3=David |title=O-linked protein glycosylation structure and function |journal=Glycoconjugate Journal |date=1995 |volume=13 |pages=19–26 |doi=10.1007/bf01049675}}</ref> Because of the many functions they have, changes in ''O''-glycosylation are important in many diseases including [[cancer]], [[diabetes]] and [[Alzheimer's]]. ''O''-glycosylation occurs in all domains of life, including [[eukaryotes]], [[archaea]] and a number of [[pathogenic]] bacteria including ''Burkholderia cenocepacia'',<ref name ="Lithgow 2014">{{Cite journal|last=Lithgow|first=Karen V.|last2=Scott|first2=Nichollas E.|last3=Iwashkiw|first3=Jeremy A.|last4=Thomson|first4=Euan L. S.|last5=Foster|first5=Leonard J.|last6=Feldman|first6=Mario F.|last7=Dennis|first7=Jonathan J.|date=April 2014|title=A general protein ''O''-glycosylation system within the ''Burkholderia cepacia'' complex is involved in motility and virulence|journal=Molecular Microbiology|volume=92|issue=1|pages=116–137|doi=10.1111/mmi.12540|issn=1365-2958|pmid=24673753}}</ref> ''Neisseria gonorrhoeae'' <ref name ="Vik 2009">{{Cite journal|last=Vik|first=Ashild|last2=Aas|first2=Finn Erik|last3=Anonsen|first3=Jan Haug|last4=Bilsborough|first4=Shaun|last5=Schneider|first5=Andrea|last6=Egge-Jacobsen|first6=Wolfgang|last7=Koomey|first7=Michael|date=2009-03-17|title=Broad spectrum ''O''-linked protein glycosylation in the human pathogen ''Neisseria gonorrhoeae''|journal=Proceedings of the National Academy of Sciences of the United States of America|volume=106|issue=11|pages=4447–4452|doi=10.1073/pnas.0809504106|issn=1091-6490|pmc=2648892|pmid=19251655|bibcode=2009PNAS..106.4447V}}</ref> and ''Acinetobacter baumannii''.<ref name ="Iwashkiw 2012">{{Cite journal|last=Iwashkiw|first=Jeremy A.|last2=Seper|first2=Andrea|last3=Weber|first3=Brent S.|last4=Scott|first4=Nichollas E.|last5=Vinogradov|first5=Evgeny|last6=Stratilo|first6=Chad|last7=Reiz|first7=Bela|last8=Cordwell|first8=Stuart J.|last9=Whittal|first9=Randy|date=2012|title=Identification of a general ''O''-linked protein glycosylation system in ''Acinetobacter baumannii'' and its role in virulence and biofilm formation|journal=PLoS Pathogens|volume=8|issue=6|pages=e1002758|doi=10.1371/journal.ppat.1002758|issn=1553-7374|pmc=3369928|pmid=22685409}}</ref>
'''''O''-linked glycosylation''' is the attachment of a [[sugar]] molecule to the [[oxygen]] atom of serine (Ser) or threonine (Thr) residues in a protein. '''''O''-glycosylation''' is a [[post-translational modification]] that occurs after the protein has been synthesised. In [[eukaryote]]s, it occurs in the [[endoplasmic reticulum]], [[Golgi apparatus]] and occasionally in the [[cytoplasm]]; in [[prokaryote]]s, it occurs in the cytoplasm.<ref name="Steen 1998">{{cite journal |last1=Van den Steen |first1=Philippe |last2=M. Rudd |first2=Pauline |last3=A. Dwek |first3=Raymond |last4=Opdenakker |first4=Ghislain |title=Concepts and Principles of ''O''-Linked Glycosylation |journal=Critical Reviews in Biochemistry and Molecular Biology |date=1998 |volume=33 |issue=3 |pages=151–208 |doi=10.1080/10409239891204198}}</ref> Several different sugars can be added to the serine or threonine, and they affect the protein in different ways by changing protein stability and regulating protein activity. ''O''-glycans, which are the sugars added to the serine or threonine, have numerous functions throughout the body, including trafficking of cells in the immune system, allowing recognition of foreign material, controlling cell [[metabolism]] and providing cartilage and tendon flexibility.<ref name="Hounsell 1995">{{cite journal |last1=F. Hounsell |first1=Elizabeth |last2=J. Davies |first2=Michael |last3=V. Renouf |first3=David |title=''O''-linked protein glycosylation structure and function |journal=Glycoconjugate Journal |date=1995 |volume=13 |pages=19–26 |doi=10.1007/bf01049675}}</ref> Because of the many functions they have, changes in ''O''-glycosylation are important in many diseases including [[cancer]], [[diabetes]] and [[Alzheimer's]]. ''O''-glycosylation occurs in all domains of life, including [[eukaryotes]], [[archaea]] and a number of [[pathogenic]] bacteria including ''Burkholderia cenocepacia'',<ref name ="Lithgow 2014">{{Cite journal|last=Lithgow|first=Karen V.|last2=Scott|first2=Nichollas E.|last3=Iwashkiw|first3=Jeremy A.|last4=Thomson|first4=Euan L. S.|last5=Foster|first5=Leonard J.|last6=Feldman|first6=Mario F.|last7=Dennis|first7=Jonathan J.|date=April 2014|title=A general protein ''O''-glycosylation system within the ''Burkholderia cepacia'' complex is involved in motility and virulence|journal=Molecular Microbiology|volume=92|issue=1|pages=116–137|doi=10.1111/mmi.12540|issn=1365-2958|pmid=24673753}}</ref> ''Neisseria gonorrhoeae'' <ref name ="Vik 2009">{{Cite journal|last=Vik|first=Ashild|last2=Aas|first2=Finn Erik|last3=Anonsen|first3=Jan Haug|last4=Bilsborough|first4=Shaun|last5=Schneider|first5=Andrea|last6=Egge-Jacobsen|first6=Wolfgang|last7=Koomey|first7=Michael|date=2009-03-17|title=Broad spectrum ''O''-linked protein glycosylation in the human pathogen ''Neisseria gonorrhoeae''|journal=Proceedings of the National Academy of Sciences of the United States of America|volume=106|issue=11|pages=4447–4452|doi=10.1073/pnas.0809504106|issn=1091-6490|pmc=2648892|pmid=19251655|bibcode=2009PNAS..106.4447V}}</ref> and ''Acinetobacter baumannii''.<ref name ="Iwashkiw 2012">{{Cite journal|last=Iwashkiw|first=Jeremy A.|last2=Seper|first2=Andrea|last3=Weber|first3=Brent S.|last4=Scott|first4=Nichollas E.|last5=Vinogradov|first5=Evgeny|last6=Stratilo|first6=Chad|last7=Reiz|first7=Bela|last8=Cordwell|first8=Stuart J.|last9=Whittal|first9=Randy|date=2012|title=Identification of a general ''O''-linked protein glycosylation system in ''Acinetobacter baumannii'' and its role in virulence and biofilm formation|journal=PLoS Pathogens|volume=8|issue=6|pages=e1002758|doi=10.1371/journal.ppat.1002758|issn=1553-7374|pmc=3369928|pmid=22685409}}</ref>


==Common Types of O-Glycosylation==
==Common types of ''O''-glycosylation==


===''O''-''N''-acetylgalactosamine (''O''-GalNAc)===
===''O''-''N''-acetylgalactosamine (''O''-GalNAc)===


[[File:Core1, Core 2 and Poly-N-acetyllactosamine structures.png|upright=1.1|right|thumb| Common O-GalNAc core structures; Core 1, Core 2 and poly-N-acetyllactosamine structures.]]
[[File:Core1, Core 2 and Poly-N-acetyllactosamine structures.png|upright=1.1|right|thumb| Common ''O''-GalNAc core structures; Core 1, Core 2 and poly-''N''-acetyllactosamine structures.]]


Addition of [[N-acetylgalactosamine]] (GalNAc) to a serine or threonine occurs in the [[Golgi apparatus]], after the protein has been folded.<ref name ="Steen 1998"/><ref name="Varki 2015">{{cite book |last1=Varki |first1=Ajit |title=Essentials of glycobiology |date=2015 |publisher=Cold Spring Harbor Laboratory Press |location=Cold Spring Harbor, New York |isbn=9781621821328 |edition= 3rd}}</ref> The process is performed by [[enzymes]] known as GalNAc [[transferases]] (GALNTs), of which there are 20 different types.<ref name="Varki 2015"/> The initial ''O''-GalNAc structure can be modified by the addition of other sugars, or other compounds such as methyl and acetyl groups.<ref name ="Steen 1998"/> These modifications produce 8 core structures known to date.<ref name="Hounsell 1995" /> Different cells have different enzymes that can add further sugars, known as [[glycosyltransferases]], and structures therefore change from cell to cell.<ref name="Varki 2015"/> Common sugars added include [[galactose]], [[N-acetylglucosamine]], [[fucose]] and [[sialic acid]]. These sugars can also be modified by the addition of sulfates or acetyl groups.
Addition of [[N-acetylgalactosamine|''N''-acetylgalactosamine]] (GalNAc) to a serine or threonine occurs in the [[Golgi apparatus]], after the protein has been folded.<ref name ="Steen 1998"/><ref name="Varki 2015">{{cite book |last1=Varki |first1=Ajit |title=Essentials of glycobiology |date=2015 |publisher=Cold Spring Harbor Laboratory Press |location=Cold Spring Harbor, New York |isbn=9781621821328 |edition= 3rd}}</ref> The process is performed by [[enzymes]] known as GalNAc [[transferases]] (GALNTs), of which there are 20 different types.<ref name="Varki 2015"/> The initial ''O''-GalNAc structure can be modified by the addition of other sugars, or other compounds such as methyl and acetyl groups.<ref name ="Steen 1998"/> These modifications produce 8 core structures known to date.<ref name="Hounsell 1995" /> Different cells have different enzymes that can add further sugars, known as [[glycosyltransferases]], and structures therefore change from cell to cell.<ref name="Varki 2015"/> Common sugars added include [[galactose]], [[N-acetylglucosamine|''N''-acetylglucosamine]], [[fucose]] and [[sialic acid]]. These sugars can also be modified by the addition of sulfates or acetyl groups.


[[File:Sugars that form the H, A and B antigens.png|upright=1|left|thumb| ''N''-acetylgalactosamine (GalNAc) can be added to the H-antigen to form the A-antigen. Galactose (Gal) can be added to form the B-antigen.]]
[[File:Sugars that form the H, A and B antigens.png|upright=1|left|thumb| ''N''-acetylgalactosamine (GalNAc) can be added to the H-antigen to form the A-antigen. Galactose (Gal) can be added to form the B-antigen.]]
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GalNAc is added onto a serine or threonine residue from a [[Precursor (chemistry)|precursor molecule]], through the activity of a GalNAc transferase enzyme.<ref name ="Steen 1998"/> This precursor is necessary so that the sugar can be transported to where it will be added to the protein. The specific residue onto which GalNAc will be attached is not defined, because there are numerous enzymes that can add the sugar and each one will favour different residues.<ref name="Spiro 2002">{{cite journal |last1=G. Spiro |first1=Robert |title=Protein glycosylation: nature, distribution, enzymatic formation, and disease implications of glycopeptide bonds |journal=Glycobiology |date=2002 |volume=12 |issue=4 |pages=43R-56R |doi=10.1093/glycob/12.4.43R}}</ref> However, there are often proline (Pro) residues near the threonine or serine.<ref name="Varki 2015"/>
GalNAc is added onto a serine or threonine residue from a [[Precursor (chemistry)|precursor molecule]], through the activity of a GalNAc transferase enzyme.<ref name ="Steen 1998"/> This precursor is necessary so that the sugar can be transported to where it will be added to the protein. The specific residue onto which GalNAc will be attached is not defined, because there are numerous enzymes that can add the sugar and each one will favour different residues.<ref name="Spiro 2002">{{cite journal |last1=G. Spiro |first1=Robert |title=Protein glycosylation: nature, distribution, enzymatic formation, and disease implications of glycopeptide bonds |journal=Glycobiology |date=2002 |volume=12 |issue=4 |pages=43R-56R |doi=10.1093/glycob/12.4.43R}}</ref> However, there are often proline (Pro) residues near the threonine or serine.<ref name="Varki 2015"/>


Once this initial sugar has been added, other glycosyltransferases can catalyse the addition of additional sugars. Two of the most common structures formed are Core 1 and Core 2. Core 1 is formed by the addition of a galactose sugar onto the initial GalNAc. Core 2 consists of a Core 1 structure with an additional ''N''-acetylglucosamine (GlcNAc) sugar.<ref name="Varki 2015"/> A poly-N-acetyllactosamine structure can be formed by the alternating addition of GlcNAc and galactose sugars onto the GalNAc sugar.<ref name="Varki 2015"/> A sugar containing galactose and GlcNAc is known as [[lactose]], giving the structure its name.
Once this initial sugar has been added, other glycosyltransferases can catalyse the addition of additional sugars. Two of the most common structures formed are Core 1 and Core 2. Core 1 is formed by the addition of a galactose sugar onto the initial GalNAc. Core 2 consists of a Core 1 structure with an additional ''N''-acetylglucosamine (GlcNAc) sugar.<ref name="Varki 2015"/> A poly-''N''-acetyllactosamine structure can be formed by the alternating addition of GlcNAc and galactose sugars onto the GalNAc sugar.<ref name="Varki 2015"/> A sugar containing galactose and GlcNAc is known as [[lactose]], giving the structure its name.


Terminal sugars on ''O''-glycans are important in recognition by [[lectins]] and play a key role in the immune system. Addition of fucose sugars by fucosyltransferases forms Lewis epitopes and the scaffold for blood group determinants. Addition of a fucose alone creates the H-antigen, present in people with blood type O.<ref name="Varki 2015"/> By adding a galactose onto this structure, the B-antigen of blood group B is created. Alternatively, adding a GalNAc sugar will create the A-antigen for blood group A.
Terminal sugars on ''O''-glycans are important in recognition by [[lectins]] and play a key role in the immune system. Addition of fucose sugars by fucosyltransferases forms Lewis epitopes and the scaffold for blood group determinants. Addition of a fucose alone creates the H-antigen, present in people with blood type O.<ref name="Varki 2015"/> By adding a galactose onto this structure, the B-antigen of blood group B is created. Alternatively, adding a GalNAc sugar will create the A-antigen for blood group A.
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''O''-GalNAc sugars are common on membrane [[glycoproteins]], where they help increase rigidity of the region close to the membrane so that the protein extends away from the surface.<ref name="Varki 2015"/> For example, the low-density lipoprotein receptor (LDL) is projected from the cell surface by a region rigidified by ''O''-glycans.<ref name="Hounsell 1995"/>
''O''-GalNAc sugars are common on membrane [[glycoproteins]], where they help increase rigidity of the region close to the membrane so that the protein extends away from the surface.<ref name="Varki 2015"/> For example, the low-density lipoprotein receptor (LDL) is projected from the cell surface by a region rigidified by ''O''-glycans.<ref name="Hounsell 1995"/>


In order for leukocytes of the immune system to move into infected cells, they have to interact with these cells through [[Receptor (biochemistry)|receptors]]. Leukocytes express [[ligands]] on their cell surface to allow this interaction to occur.<ref name ="Steen 1998"/> P-selectin glycoprotein ligand-1 (PSGL-1) is such a ligand, and contains a lot of O-glycans that are necessary for its function. ''O''-glycans near the membrane maintain the elongated structure and a terminal sLe<sup>x</sup> epitope is necessary for interactions with the receptor.<ref name="Taylor 2011">{{cite book |last1=E. Taylor |first1=Mauren |last2=Drickamer |first2=Kurt |title=Introduction to Glycobiology |date=2011 |publisher=Oxford University Press Inc. |location=New York |isbn=978-0-19-956911-3 |edition= 3rd}}</ref>
In order for leukocytes of the immune system to move into infected cells, they have to interact with these cells through [[Receptor (biochemistry)|receptors]]. Leukocytes express [[ligands]] on their cell surface to allow this interaction to occur.<ref name ="Steen 1998"/> P-selectin glycoprotein ligand-1 (PSGL-1) is such a ligand, and contains a lot of ''O''-glycans that are necessary for its function. ''O''-glycans near the membrane maintain the elongated structure and a terminal sLe<sup>x</sup> epitope is necessary for interactions with the receptor.<ref name="Taylor 2011">{{cite book |last1=E. Taylor |first1=Mauren |last2=Drickamer |first2=Kurt |title=Introduction to Glycobiology |date=2011 |publisher=Oxford University Press Inc. |location=New York |isbn=978-0-19-956911-3 |edition= 3rd}}</ref>


[[Mucin]]s are a group of heavily ''O''-glycosylated proteins that line the gastrointestinal and respiratory tracts to protect these regions from infection.<ref name="Varki 2015"/> Mucins are negatively charged, which allows them to interact with water and prevent it from evaporating. This is important in their protective function as it lubricates the tracts so bacteria cannot bind and infect the body. Changes in mucins are important in numerous diseases, including [[cancer]] and [[inflammatory bowel disease]]. Absence of ''O''-glycans on mucin proteins changes their 3D shape dramatically and often prevents correct function.<ref name ="Steen 1998"/><ref name="Varki 1999">{{cite book |last1=Varki |first1=Ajit |title=Essentials of Glycobiology |date=1999 |publisher=Cold Spring Harbor Laboratory Press |location=Cold Spring Harbor, New York}}</ref>
[[Mucin]]s are a group of heavily ''O''-glycosylated proteins that line the gastrointestinal and respiratory tracts to protect these regions from infection.<ref name="Varki 2015"/> Mucins are negatively charged, which allows them to interact with water and prevent it from evaporating. This is important in their protective function as it lubricates the tracts so bacteria cannot bind and infect the body. Changes in mucins are important in numerous diseases, including [[cancer]] and [[inflammatory bowel disease]]. Absence of ''O''-glycans on mucin proteins changes their 3D shape dramatically and often prevents correct function.<ref name ="Steen 1998"/><ref name="Varki 1999">{{cite book |last1=Varki |first1=Ajit |title=Essentials of Glycobiology |date=1999 |publisher=Cold Spring Harbor Laboratory Press |location=Cold Spring Harbor, New York}}</ref>


===O-N-acetylglucosamine (O-GlcNAc)===
===''O''-''N''-acetylglucosamine (''O''-GlcNAc)===


Addition of [[N-acetylglucosamine]] (''O''-GlcNAc) to serine and threonine residues usually occurs on cytoplasmic and nuclear proteins that remain in the cell, while ''O''-GalNAc modifications usually occur on proteins that will be secreted.<ref name="Yang 2017">{{cite journal |last1=Yang |first1=Xiaoyong |last2=Qian |first2=Kevin |title=Protein O-GlcNAcylation: emerging mechanisms and functions |journal=Nature Reviews Molecular Cell Biology |date=2017 |volume=18 |pages=452–465 |doi=10.1038/nrm.2017.22|pmc=5667541 }}</ref> The modification was only recently discovered, but the number of proteins with it is increasing rapidly.<ref name="Spiro 2002"/> It is the first example of glycosylation that does not occur on secretory proteins.
Addition of [[N-acetylglucosamine|''N''-acetylglucosamine]] (''O''-GlcNAc) to serine and threonine residues usually occurs on cytoplasmic and nuclear proteins that remain in the cell, while ''O''-GalNAc modifications usually occur on proteins that will be secreted.<ref name="Yang 2017">{{cite journal |last1=Yang |first1=Xiaoyong |last2=Qian |first2=Kevin |title=Protein ''O''-GlcNAcylation: emerging mechanisms and functions |journal=Nature Reviews Molecular Cell Biology |date=2017 |volume=18 |pages=452–465 |doi=10.1038/nrm.2017.22|pmc=5667541 }}</ref> The modification was only recently discovered, but the number of proteins with it is increasing rapidly.<ref name="Spiro 2002"/> It is the first example of glycosylation that does not occur on secretory proteins.


[[File:O-GlcNAc modification by OGT and OGA.png|upright=0.9|left|thumb| ''O''-GlcNAc is added to the protein by ''O''-GlcNAc transferase and is removed by ''O''-GlcNAcase in a continuous cycle.]]
[[File:O-GlcNAc modification by OGT and OGA.png|upright=0.9|left|thumb| ''O''-GlcNAc is added to the protein by ''O''-GlcNAc transferase and is removed by ''O''-GlcNAcase in a continuous cycle.]]


''O''-GlcNAcylation differs from other ''O''-glycosylation processes because there are usually no sugars added onto the core structure and because the sugar can be attached or removed from a protein several times.<ref name="Varki 2015"/><ref name="Spiro 2002"/> This addition and removal occurs in cycles and is performed by two very specific enzymes. ''O''-GlcNAc is added by [[O-GlcNAc transferase]] (OGT) and removed by [[O-GlcNAcase]] (OGA). Because there are only two enzymes that affect this specific modification, they are very tightly regulated and depend on a lot of other factors.<ref name="Lazarus 2013">{{cite journal |last1=B. Lazarus |first1=Michael |last2=Jiang |first2=Jiaoyang |last3=Kapuria |first3=Vaibhav |last4=Bhuiyan |first4=Tanja |last5=Janetzko |first5=John |last6=F. Zandberg |first6=Wesley |last7=J. Vocadlo |first7=David |last8=Herr |first8=Winship |last9=Walker |first9=Suzanne |title=HCF-1 is LCeaved in the Active Site of ''O''-GlcNAc Transferase |journal=Science |date=2013 |volume=342 |issue=6163 |pages=1235–1239 |doi=10.1126/science.1243990|pmc=3930058 }}</ref>
''O''-GlcNAcylation differs from other ''O''-glycosylation processes because there are usually no sugars added onto the core structure and because the sugar can be attached or removed from a protein several times.<ref name="Varki 2015"/><ref name="Spiro 2002"/> This addition and removal occurs in cycles and is performed by two very specific enzymes. ''O''-GlcNAc is added by [[O-GlcNAc transferase|''O''-GlcNAc transferase]] (OGT) and removed by [[O-GlcNAcase|''O''-GlcNAcase]] (OGA). Because there are only two enzymes that affect this specific modification, they are very tightly regulated and depend on a lot of other factors.<ref name="Lazarus 2013">{{cite journal |last1=B. Lazarus |first1=Michael |last2=Jiang |first2=Jiaoyang |last3=Kapuria |first3=Vaibhav |last4=Bhuiyan |first4=Tanja |last5=Janetzko |first5=John |last6=F. Zandberg |first6=Wesley |last7=J. Vocadlo |first7=David |last8=Herr |first8=Winship |last9=Walker |first9=Suzanne |title=HCF-1 is Cleaved in the Active Site of ''O''-GlcNAc Transferase |journal=Science |date=2013 |volume=342 |issue=6163 |pages=1235–1239 |doi=10.1126/science.1243990|pmc=3930058 }}</ref>


Because ''O''-GlcNAc can be added and removed, it is known as a dynamic modification and has a lot of similarities to [[phosphorylation]]. ''O''-GlcNAcylation and phosphorylation can occur on the same threonine and serine residues, suggesting a complex relationship between these modifications that can affect many functions of the cell.<ref name="Varki 2015"/><ref name="Hart 2011">{{cite journal |last1=W. Hart |first1=Gerald |last2=Slawson |first2=Chad |last3=Ramirez-Correa |first3=Genaro |last4=Lagerlof |first4=Olof |title=Cross Talk Between O-GlcNAcylation and Phosphorylation: Roles in Signaling, Transcription and Chronic Disease |journal=Annual Review of Biochemistry |date=2011 |volume=80 |issue=1 |pages=825–858 |doi=10.1146/annurev-biochem-060608-102511}}</ref> The modification affects processes like the cells response to cellular stress, the cell cycle, protein stability and protein turnover. It may be implicated in neurodegenerative diseases like [[Parkinson’s]] and late-onset [[Alzheimer’s]] <ref name ="Steen 1998"/><ref name ="Hart 2011"/> and has been found to play a role in [[diabetes]].<ref name="Ma 2014">{{cite journal |last1=Ma |first1=Junfeng |last2=W. Hart |first2=Gerald |title=Protein ''O''-GlcNAcylation in diabetes and diabetic complications |journal=Expert Review of Proteomics |date=2014 |volume=10 |issue=4 |pages=365–380 |doi=10.1586/14789450.2013.820536}}</ref>
Because ''O''-GlcNAc can be added and removed, it is known as a dynamic modification and has a lot of similarities to [[phosphorylation]]. ''O''-GlcNAcylation and phosphorylation can occur on the same threonine and serine residues, suggesting a complex relationship between these modifications that can affect many functions of the cell.<ref name="Varki 2015"/><ref name="Hart 2011">{{cite journal |last1=W. Hart |first1=Gerald |last2=Slawson |first2=Chad |last3=Ramirez-Correa |first3=Genaro |last4=Lagerlof |first4=Olof |title=Cross Talk Between ''O''-GlcNAcylation and Phosphorylation: Roles in Signaling, Transcription and Chronic Disease |journal=Annual Review of Biochemistry |date=2011 |volume=80 |issue=1 |pages=825–858 |doi=10.1146/annurev-biochem-060608-102511}}</ref> The modification affects processes like the cells response to cellular stress, the cell cycle, protein stability and protein turnover. It may be implicated in neurodegenerative diseases like [[Parkinson’s]] and late-onset [[Alzheimer’s]] <ref name ="Steen 1998"/><ref name ="Hart 2011"/> and has been found to play a role in [[diabetes]].<ref name="Ma 2014">{{cite journal |last1=Ma |first1=Junfeng |last2=W. Hart |first2=Gerald |title=Protein ''O''-GlcNAcylation in diabetes and diabetic complications |journal=Expert Review of Proteomics |date=2014 |volume=10 |issue=4 |pages=365–380 |doi=10.1586/14789450.2013.820536}}</ref>


Additionally, ''O''-GlcNAcylation can enhance the [[Warburg effect (oncology)|Warburg Effect]], which is defined as the change that occurs in the [[metabolism]] of cancer cells to favour their growth.<ref name="Varki 2015"/><ref>{{cite journal |last1=Muniz de Quieroz |first1=Rafaela |last2=Carvalho |first2=Erika |last3=Barbosa Dias |first3=Wagner |title=O-GlcNAcylation: the sweet side of the cancer |journal=Frontiers in Oncology |date=2014 |volume=4 |pages=132 |doi=10.3389/fonc.2014.00132}}</ref> Because both ''O''-GlcNAcylation and phosphorylation can affect specific residues and therefore both have important functions in regulating signalling pathways, both of these processes provide interesting targets for cancer research.
Additionally, ''O''-GlcNAcylation can enhance the [[Warburg effect (oncology)|Warburg Effect]], which is defined as the change that occurs in the [[metabolism]] of cancer cells to favour their growth.<ref name="Varki 2015"/><ref>{{cite journal |last1=Muniz de Quieroz |first1=Rafaela |last2=Carvalho |first2=Erika |last3=Barbosa Dias |first3=Wagner |title=''O''-GlcNAcylation: the sweet side of the cancer |journal=Frontiers in Oncology |date=2014 |volume=4 |pages=132 |doi=10.3389/fonc.2014.00132}}</ref> Because both ''O''-GlcNAcylation and phosphorylation can affect specific residues and therefore both have important functions in regulating signalling pathways, both of these processes provide interesting targets for cancer research.


===''O''-Mannose (''O''-Man)===
===''O''-Mannose (''O''-Man)===
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[[File:Common O-glycans found on alpha-dystroglycan.png|upright=0.7|right|thumb| ''O''-Mannose sugars attached to serine and threonine residues on α-dystroglycan separate the two domains of the protein. Addition of Ribitol-P, xylose and glucuronic acid forms a long sugar that can stabilise the interaction with the basement membrane.]]
[[File:Common O-glycans found on alpha-dystroglycan.png|upright=0.7|right|thumb| ''O''-Mannose sugars attached to serine and threonine residues on α-dystroglycan separate the two domains of the protein. Addition of Ribitol-P, xylose and glucuronic acid forms a long sugar that can stabilise the interaction with the basement membrane.]]


''O''-mannosylation involves the transfer of a [[mannose]] from a dolichol-P-mannose donor molecule onto the serine or threonine residue of a protein.<ref name="Strahl 2009">{{cite journal |last1=Strahl |first1=Sabine |last2=Lommel |first2=Mark |title=Protein ''O''-mannosylation: Conserved from bacteria to humans |journal=Glycobiology |date=2009 |volume=19 |issue=8 |pages=816–828 |doi=10.1093/glycob/cwp066}}</ref> Most other ''O''-glycosylation processes use a sugar nucleotide as a donor molecule.<ref name="Spiro 2002"/> A further difference from other ''O''-glycosylations is that the process is initiated in the endoplasmic reticulum of the cell, rather than the Golgi apparatus.<ref name ="Steen 1998"/> However, further addition of sugars occurs in the Golgi.<ref name="Strahl 2009"/>
''O''-mannosylation involves the transfer of a [[mannose]] from a dolichol-''P''-mannose donor molecule onto the serine or threonine residue of a protein.<ref name="Strahl 2009">{{cite journal |last1=Strahl |first1=Sabine |last2=Lommel |first2=Mark |title=Protein ''O''-mannosylation: Conserved from bacteria to humans |journal=Glycobiology |date=2009 |volume=19 |issue=8 |pages=816–828 |doi=10.1093/glycob/cwp066}}</ref> Most other ''O''-glycosylation processes use a sugar nucleotide as a donor molecule.<ref name="Spiro 2002"/> A further difference from other ''O''-glycosylations is that the process is initiated in the endoplasmic reticulum of the cell, rather than the Golgi apparatus.<ref name ="Steen 1998"/> However, further addition of sugars occurs in the Golgi.<ref name="Strahl 2009"/>


Until recently, it was believed that the process is restricted to [[fungi]], however it occurs in all domains of life; eukaryotes, (eu)bacteria and archae(bacteri)a.<ref name="Bolsinger 1999">{{cite journal |last1=Strahl-Bolsinger |first1=Sabine |last2=Gentzsch |first2=Martina |last3=Tanner |first3=Widmar |title=Protein ''O''-mannosylation |journal=biochimica et Biophysica Acta |date=1999 |volume=1426 |issue=2 |pages=297–307 |doi=10.1016/S0304-4165(98)00131-7}}</ref> The best characterised O-mannosylated human protein is [[dystroglycan|α-dystroglycan]].<ref name="Strahl 2009"/> ''O''-Man sugars separate two domains of the protein, required to connect the extracellular and intracellular regions to anchor the cell in position.<ref name="Inamori 2012">{{cite journal |last1=Inamori |first1=Kei-ichiro |last2=Yoshida-Moriguchi |first2=Takako |last3=Hara |first3=Yuji |last4=E. Anderson |first4=Mary |last5=Yu |first5=Liping |last6=P. Campbell |first6=Kevin |title=Dystroglycan Function Requires Xylosyl- and Glucuronyltransferase Activities of LARGE |journal=Science |date=2012 |volume=335 |issue=6064 |pages=93–96 |doi=10.1126/science.1214115}}</ref> [[Ribitol]], [[xylose]] and [[glucuronic acid]] can be added to this structure in a complex modification that forms a long sugar chain.<ref name="Taylor 2011"/> This is required to stabilise the interaction between α-dystroglycan and the extracellular basement membrane. Without these modifications, the glycoprotein cannot anchor the cell which leads to [[congenital muscular dystrophy]] (CMD), characterised by severe brain malformations.<ref name="Strahl 2009"/>
Until recently, it was believed that the process is restricted to [[fungi]], however it occurs in all domains of life; eukaryotes, (eu)bacteria and archae(bacteri)a.<ref name="Bolsinger 1999">{{cite journal |last1=Strahl-Bolsinger |first1=Sabine |last2=Gentzsch |first2=Martina |last3=Tanner |first3=Widmar |title=Protein ''O''-mannosylation |journal=biochimica et Biophysica Acta |date=1999 |volume=1426 |issue=2 |pages=297–307 |doi=10.1016/S0304-4165(98)00131-7}}</ref> The best characterised ''O''-mannosylated human protein is [[dystroglycan|α-dystroglycan]].<ref name="Strahl 2009"/> ''O''-Man sugars separate two domains of the protein, required to connect the extracellular and intracellular regions to anchor the cell in position.<ref name="Inamori 2012">{{cite journal |last1=Inamori |first1=Kei-ichiro |last2=Yoshida-Moriguchi |first2=Takako |last3=Hara |first3=Yuji |last4=E. Anderson |first4=Mary |last5=Yu |first5=Liping |last6=P. Campbell |first6=Kevin |title=Dystroglycan Function Requires Xylosyl- and Glucuronyltransferase Activities of LARGE |journal=Science |date=2012 |volume=335 |issue=6064 |pages=93–96 |doi=10.1126/science.1214115}}</ref> [[Ribitol]], [[xylose]] and [[glucuronic acid]] can be added to this structure in a complex modification that forms a long sugar chain.<ref name="Taylor 2011"/> This is required to stabilise the interaction between α-dystroglycan and the extracellular basement membrane. Without these modifications, the glycoprotein cannot anchor the cell which leads to [[congenital muscular dystrophy]] (CMD), characterised by severe brain malformations.<ref name="Strahl 2009"/>


===''O''-Galactose (''O''-Gal)===
===''O''-Galactose (''O''-Gal)===
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===''O''-Fucose (''O''-Fuc)===
===''O''-Fucose (''O''-Fuc)===


Addition of [[fucose]] sugars to serine and threonine residues is an unusual form of ''O''-glycosylation that occurs in the endoplasmic reticulum and is catalysed by two fucosyltransferases.<ref name="Moloney 1997">{{cite journal |last1=J. Moloney |first1=Daniel |last2=I. Lin |first2=Angy |last3=S. Haltiwanger |first3=Robert |title=The ''O''-linked Fucose Glycosylation Pathway |journal=Journal of Biological Chemistry |date=1997 |volume=272 |pages=19046–19050 |doi=10.1074/jbc.272.30.19046}}</ref> These were discovered in ''Plasmodium falciparum'' <ref name ="Lopaticki 2017">{{cite journal |last1=Lopaticki |first1=S |last2=Yang |first2=ASP |last3=John |first3=A |last4=Scott |first4=NE |last5=Lingford |first5=JP |last6=O'Neill |first6=MT |last7=Erickson |first7=SM |last8=McKenzie |first8=NC |last9=Jennison |first9=C |last10=Whitehead |first10=LW |last11=Douglas |first11=DN |last12=Kneteman |first12=NM |last13=Goddard-Borger |first13=ED |last14=Boddey |first14=JA |title=Protein ''O''-fucosylation in ''Plasmodium falciparum'' ensures efficient infection of mosquito and vertebrate hosts. |journal=Nature Communications |date=15 September 2017 |volume=8 |issue=1 |pages=561 |doi=10.1038/s41467-017-00571-y |pmid=28916755|pmc=5601480 |bibcode=2017NatCo...8..561L }}</ref> and ''Toxoplasma gondii''.<ref name ="Khurana 2018">{{Cite journal|last=Khurana|first=Sachin|last2=Coffey|first2=Michael J.|last3=John|first3=Alan|last4=Uboldi|first4=Alessandro D.|last5=Huynh|first5=My-Hang|last6=Stewart|first6=Rebecca J.|last7=Carruthers|first7=Vern|last8=Tonkin|first8=Christopher J.|last9=Goddard-Borger|first9=Ethan D.|date=2018-12-04|title=Protein O-fucosyltransferase 2-mediated ''O''-glycosylation of the adhesin MIC2 is dispensable for ''Toxoplasma gondii'' tachyzoite infection|journal=The Journal of Biological Chemistry|pages=jbc.RA118.005357|doi=10.1074/jbc.RA118.005357|issn=1083-351X|pmid=30514763|volume=294|pmc=6364784}}</ref>
Addition of [[fucose]] sugars to serine and threonine residues is an unusual form of ''O''-glycosylation that occurs in the endoplasmic reticulum and is catalysed by two fucosyltransferases.<ref name="Moloney 1997">{{cite journal |last1=J. Moloney |first1=Daniel |last2=I. Lin |first2=Angy |last3=S. Haltiwanger |first3=Robert |title=The ''O''-linked Fucose Glycosylation Pathway |journal=Journal of Biological Chemistry |date=1997 |volume=272 |pages=19046–19050 |doi=10.1074/jbc.272.30.19046}}</ref> These were discovered in ''Plasmodium falciparum'' <ref name ="Lopaticki 2017">{{cite journal |last1=Lopaticki |first1=S |last2=Yang |first2=ASP |last3=John |first3=A |last4=Scott |first4=NE |last5=Lingford |first5=JP |last6=O'Neill |first6=MT |last7=Erickson |first7=SM |last8=McKenzie |first8=NC |last9=Jennison |first9=C |last10=Whitehead |first10=LW |last11=Douglas |first11=DN |last12=Kneteman |first12=NM |last13=Goddard-Borger |first13=ED |last14=Boddey |first14=JA |title=Protein ''O''-fucosylation in ''Plasmodium falciparum'' ensures efficient infection of mosquito and vertebrate hosts. |journal=Nature Communications |date=15 September 2017 |volume=8 |issue=1 |pages=561 |doi=10.1038/s41467-017-00571-y |pmid=28916755|pmc=5601480 |bibcode=2017NatCo...8..561L }}</ref> and ''Toxoplasma gondii''.<ref name ="Khurana 2018">{{Cite journal|last=Khurana|first=Sachin|last2=Coffey|first2=Michael J.|last3=John|first3=Alan|last4=Uboldi|first4=Alessandro D.|last5=Huynh|first5=My-Hang|last6=Stewart|first6=Rebecca J.|last7=Carruthers|first7=Vern|last8=Tonkin|first8=Christopher J.|last9=Goddard-Borger|first9=Ethan D.|date=2018-12-04|title=Protein ''O''-fucosyltransferase 2-mediated ''O''-glycosylation of the adhesin MIC2 is dispensable for ''Toxoplasma gondii'' tachyzoite infection|journal=The Journal of Biological Chemistry|pages=jbc.RA118.005357|doi=10.1074/jbc.RA118.005357|issn=1083-351X|pmid=30514763|volume=294|pmc=6364784}}</ref>


Several different enzymes catalyse the elongation of the core fucose, meaning that different sugars can be added to the initial fucose on the protein.<ref name="Moloney 1997"/> Along with ''O''-glucosylation, ''O''-fucosylation is mainly found on [[epidermal growth factor]] (EGF) domains found in proteins.<ref name="Spiro 2002"/> ''O''-fucosylation on EGF domains occurs between the second and third conserved [[cysteine]] residues in the protein sequence.<ref name ="Steen 1998"/> Once the core ''O''-fucose has been added, it is often elongated by addition of GlcNAc, galactose and sialic acid.
Several different enzymes catalyse the elongation of the core fucose, meaning that different sugars can be added to the initial fucose on the protein.<ref name="Moloney 1997"/> Along with ''O''-glucosylation, ''O''-fucosylation is mainly found on [[epidermal growth factor]] (EGF) domains found in proteins.<ref name="Spiro 2002"/> ''O''-fucosylation on EGF domains occurs between the second and third conserved [[cysteine]] residues in the protein sequence.<ref name ="Steen 1998"/> Once the core ''O''-fucose has been added, it is often elongated by addition of GlcNAc, galactose and sialic acid.
Line 68: Line 68:
===''O''-Glucose (''O''-Glc)===
===''O''-Glucose (''O''-Glc)===


Similarly to ''O''-fucosylation, ''O''-glucosylation is an unusual O-linked modification as it occurs in the endoplasmic reticulum, catalysed by ''O''-glucosyltransferases, and also requires a defined sequence in order to be added to the protein. ''O''-glucose is often attached to serine residues between the first and second conserved cysteine residues of EGF domains, for example in [[clotting factors]] VII and IX.<ref name="Spiro 2002"/> ''O''-glucosylation also appears to be necessary for the proper folding of EGF domains in the Notch protein.<ref name="Takeuchi 2012">{{cite journal |last1=Takeuchi |first1=Hideyuki |last2=Kantharia |first2=Joshua |last3=K. Sethi |first3=Maya |last4=Bakker |first4=Hans |last5=S. Haltiwanger |first5=Robert |title=Site-specific ''O''-Glucosylation of the Epidermal Growth Factor-like (EGF) Repeats of NOtch |journal=Journal of Biological Chemistry |date=2012 |volume=287 |pages=33934–33944 |doi=10.1074/jbc.M112.401315}}</ref>
Similarly to ''O''-fucosylation, ''O''-glucosylation is an unusual ''O''-linked modification as it occurs in the endoplasmic reticulum, catalysed by ''O''-glucosyltransferases, and also requires a defined sequence in order to be added to the protein. ''O''-glucose is often attached to serine residues between the first and second conserved cysteine residues of EGF domains, for example in [[clotting factors]] VII and IX.<ref name="Spiro 2002"/> ''O''-glucosylation also appears to be necessary for the proper folding of EGF domains in the Notch protein.<ref name="Takeuchi 2012">{{cite journal |last1=Takeuchi |first1=Hideyuki |last2=Kantharia |first2=Joshua |last3=K. Sethi |first3=Maya |last4=Bakker |first4=Hans |last5=S. Haltiwanger |first5=Robert |title=Site-specific ''O''-Glucosylation of the Epidermal Growth Factor-like (EGF) Repeats of NOtch |journal=Journal of Biological Chemistry |date=2012 |volume=287 |pages=33934–33944 |doi=10.1074/jbc.M112.401315}}</ref>


==Proteoglycans==
==Proteoglycans==
Line 76: Line 76:
[[Proteoglycans]] consist of a protein with one or more sugar side chains, known as [[glycosaminoglycans]] (GAGs), attached to the oxygen of serine and threonine residues.<ref name="Pomin 2018">{{cite journal |last1=H. Pomin |first1=Vitor |last2=Mulloy |first2=Barbara |title=Glucosaminoglycans and Proteoglycans |journal=Pharmaceuticals |date=2018 |volume=11 |issue=1 |pages=17 |doi=10.3390/ph11010027}}</ref> GAGs consist of long chains of repeating sugar units. Proteoglycans are usually found on the cell surface and in the [[extracellular matrix]] (ECM), and are important for the strength and flexibility of cartilage and tendons. Absence of proteoglycans is associated with heart and respiratory failure, defects in skeletal development and increased tumor metastasis.<ref name= "Pomin 2018"/>
[[Proteoglycans]] consist of a protein with one or more sugar side chains, known as [[glycosaminoglycans]] (GAGs), attached to the oxygen of serine and threonine residues.<ref name="Pomin 2018">{{cite journal |last1=H. Pomin |first1=Vitor |last2=Mulloy |first2=Barbara |title=Glucosaminoglycans and Proteoglycans |journal=Pharmaceuticals |date=2018 |volume=11 |issue=1 |pages=17 |doi=10.3390/ph11010027}}</ref> GAGs consist of long chains of repeating sugar units. Proteoglycans are usually found on the cell surface and in the [[extracellular matrix]] (ECM), and are important for the strength and flexibility of cartilage and tendons. Absence of proteoglycans is associated with heart and respiratory failure, defects in skeletal development and increased tumor metastasis.<ref name= "Pomin 2018"/>


Different types of proteoglycans exist, depending on the sugar that is linked to the oxygen atom of the residue in the protein. For example, the GAG [[heparan sulphate]] is attached to a protein serine residue through a [[xylose]] sugar.<ref name="Spiro 2002"/> The structure is extended with several N-acetyllactosamine repeating sugar units added onto the xylose. This process is unusual and requires specific xylosyltransferases.<ref name="Varki 2015"/> [[Keratan sulphate]] attaches to a serine or threonine residue through GalNAc, and is extended with two galactose sugars, followed by repeating units of glucuronic acid (GlcA) and GlcNAc. Type II keratan sulphate is especially common in cartilage.<ref name="Pomin 2018"/>
Different types of proteoglycans exist, depending on the sugar that is linked to the oxygen atom of the residue in the protein. For example, the GAG [[heparan sulphate]] is attached to a protein serine residue through a [[xylose]] sugar.<ref name="Spiro 2002"/> The structure is extended with several ''N''-acetyllactosamine repeating sugar units added onto the xylose. This process is unusual and requires specific xylosyltransferases.<ref name="Varki 2015"/> [[Keratan sulphate]] attaches to a serine or threonine residue through GalNAc, and is extended with two galactose sugars, followed by repeating units of glucuronic acid (GlcA) and GlcNAc. Type II keratan sulphate is especially common in cartilage.<ref name="Pomin 2018"/>


==Lipids==
==Lipids==
Line 106: Line 106:
== See also ==
== See also ==
*[[Glycosylation]]
*[[Glycosylation]]
*[[N-linked glycosylation]]
*[[N-linked glycosylation|''N''-linked glycosylation]]


== References ==
== References ==
Line 114: Line 114:


== External links ==
== External links ==
* [http://crdd.osdd.net/raghava/glycoep/ GlycoEP] : In silico Platform for Prediction of N-, O- and C-Glycosites in Eukaryotic Protein Sequences
* [http://crdd.osdd.net/raghava/glycoep/ GlycoEP]: In silico Platform for Prediction of ''N''-, ''O''- and ''C''-Glycosites in Eukaryotic Protein Sequences


[[Category:Posttranslational modification]]
[[Category:Posttranslational modification]]

Revision as of 00:37, 14 September 2019

O-linked glycosylation is the attachment of a sugar molecule to the oxygen atom of serine (Ser) or threonine (Thr) residues in a protein. O-glycosylation is a post-translational modification that occurs after the protein has been synthesised. In eukaryotes, it occurs in the endoplasmic reticulum, Golgi apparatus and occasionally in the cytoplasm; in prokaryotes, it occurs in the cytoplasm.[1] Several different sugars can be added to the serine or threonine, and they affect the protein in different ways by changing protein stability and regulating protein activity. O-glycans, which are the sugars added to the serine or threonine, have numerous functions throughout the body, including trafficking of cells in the immune system, allowing recognition of foreign material, controlling cell metabolism and providing cartilage and tendon flexibility.[2] Because of the many functions they have, changes in O-glycosylation are important in many diseases including cancer, diabetes and Alzheimer's. O-glycosylation occurs in all domains of life, including eukaryotes, archaea and a number of pathogenic bacteria including Burkholderia cenocepacia,[3] Neisseria gonorrhoeae [4] and Acinetobacter baumannii.[5]

Common types of O-glycosylation

O-N-acetylgalactosamine (O-GalNAc)

Common O-GalNAc core structures; Core 1, Core 2 and poly-N-acetyllactosamine structures.

Addition of N-acetylgalactosamine (GalNAc) to a serine or threonine occurs in the Golgi apparatus, after the protein has been folded.[1][6] The process is performed by enzymes known as GalNAc transferases (GALNTs), of which there are 20 different types.[6] The initial O-GalNAc structure can be modified by the addition of other sugars, or other compounds such as methyl and acetyl groups.[1] These modifications produce 8 core structures known to date.[2] Different cells have different enzymes that can add further sugars, known as glycosyltransferases, and structures therefore change from cell to cell.[6] Common sugars added include galactose, N-acetylglucosamine, fucose and sialic acid. These sugars can also be modified by the addition of sulfates or acetyl groups.

N-acetylgalactosamine (GalNAc) can be added to the H-antigen to form the A-antigen. Galactose (Gal) can be added to form the B-antigen.

Biosynthesis

GalNAc is added onto a serine or threonine residue from a precursor molecule, through the activity of a GalNAc transferase enzyme.[1] This precursor is necessary so that the sugar can be transported to where it will be added to the protein. The specific residue onto which GalNAc will be attached is not defined, because there are numerous enzymes that can add the sugar and each one will favour different residues.[7] However, there are often proline (Pro) residues near the threonine or serine.[6]

Once this initial sugar has been added, other glycosyltransferases can catalyse the addition of additional sugars. Two of the most common structures formed are Core 1 and Core 2. Core 1 is formed by the addition of a galactose sugar onto the initial GalNAc. Core 2 consists of a Core 1 structure with an additional N-acetylglucosamine (GlcNAc) sugar.[6] A poly-N-acetyllactosamine structure can be formed by the alternating addition of GlcNAc and galactose sugars onto the GalNAc sugar.[6] A sugar containing galactose and GlcNAc is known as lactose, giving the structure its name.

Terminal sugars on O-glycans are important in recognition by lectins and play a key role in the immune system. Addition of fucose sugars by fucosyltransferases forms Lewis epitopes and the scaffold for blood group determinants. Addition of a fucose alone creates the H-antigen, present in people with blood type O.[6] By adding a galactose onto this structure, the B-antigen of blood group B is created. Alternatively, adding a GalNAc sugar will create the A-antigen for blood group A.

PSGL-1 has several O-glycans to extend the ligand away from the cell surface. An sLex epitope allows interactions with the receptor for leukocyte localisation.

Functions

O-GalNAc sugars are important in a variety of processes, including leukocyte circulation during an immune response, fertilisation, and protection against invading microbes.[1][2]

O-GalNAc sugars are common on membrane glycoproteins, where they help increase rigidity of the region close to the membrane so that the protein extends away from the surface.[6] For example, the low-density lipoprotein receptor (LDL) is projected from the cell surface by a region rigidified by O-glycans.[2]

In order for leukocytes of the immune system to move into infected cells, they have to interact with these cells through receptors. Leukocytes express ligands on their cell surface to allow this interaction to occur.[1] P-selectin glycoprotein ligand-1 (PSGL-1) is such a ligand, and contains a lot of O-glycans that are necessary for its function. O-glycans near the membrane maintain the elongated structure and a terminal sLex epitope is necessary for interactions with the receptor.[8]

Mucins are a group of heavily O-glycosylated proteins that line the gastrointestinal and respiratory tracts to protect these regions from infection.[6] Mucins are negatively charged, which allows them to interact with water and prevent it from evaporating. This is important in their protective function as it lubricates the tracts so bacteria cannot bind and infect the body. Changes in mucins are important in numerous diseases, including cancer and inflammatory bowel disease. Absence of O-glycans on mucin proteins changes their 3D shape dramatically and often prevents correct function.[1][9]

O-N-acetylglucosamine (O-GlcNAc)

Addition of N-acetylglucosamine (O-GlcNAc) to serine and threonine residues usually occurs on cytoplasmic and nuclear proteins that remain in the cell, while O-GalNAc modifications usually occur on proteins that will be secreted.[10] The modification was only recently discovered, but the number of proteins with it is increasing rapidly.[7] It is the first example of glycosylation that does not occur on secretory proteins.

O-GlcNAc is added to the protein by O-GlcNAc transferase and is removed by O-GlcNAcase in a continuous cycle.

O-GlcNAcylation differs from other O-glycosylation processes because there are usually no sugars added onto the core structure and because the sugar can be attached or removed from a protein several times.[6][7] This addition and removal occurs in cycles and is performed by two very specific enzymes. O-GlcNAc is added by O-GlcNAc transferase (OGT) and removed by O-GlcNAcase (OGA). Because there are only two enzymes that affect this specific modification, they are very tightly regulated and depend on a lot of other factors.[11]

Because O-GlcNAc can be added and removed, it is known as a dynamic modification and has a lot of similarities to phosphorylation. O-GlcNAcylation and phosphorylation can occur on the same threonine and serine residues, suggesting a complex relationship between these modifications that can affect many functions of the cell.[6][12] The modification affects processes like the cells response to cellular stress, the cell cycle, protein stability and protein turnover. It may be implicated in neurodegenerative diseases like Parkinson’s and late-onset Alzheimer’s [1][12] and has been found to play a role in diabetes.[13]

Additionally, O-GlcNAcylation can enhance the Warburg Effect, which is defined as the change that occurs in the metabolism of cancer cells to favour their growth.[6][14] Because both O-GlcNAcylation and phosphorylation can affect specific residues and therefore both have important functions in regulating signalling pathways, both of these processes provide interesting targets for cancer research.

O-Mannose (O-Man)

O-Mannose sugars attached to serine and threonine residues on α-dystroglycan separate the two domains of the protein. Addition of Ribitol-P, xylose and glucuronic acid forms a long sugar that can stabilise the interaction with the basement membrane.

O-mannosylation involves the transfer of a mannose from a dolichol-P-mannose donor molecule onto the serine or threonine residue of a protein.[15] Most other O-glycosylation processes use a sugar nucleotide as a donor molecule.[7] A further difference from other O-glycosylations is that the process is initiated in the endoplasmic reticulum of the cell, rather than the Golgi apparatus.[1] However, further addition of sugars occurs in the Golgi.[15]

Until recently, it was believed that the process is restricted to fungi, however it occurs in all domains of life; eukaryotes, (eu)bacteria and archae(bacteri)a.[16] The best characterised O-mannosylated human protein is α-dystroglycan.[15] O-Man sugars separate two domains of the protein, required to connect the extracellular and intracellular regions to anchor the cell in position.[17] Ribitol, xylose and glucuronic acid can be added to this structure in a complex modification that forms a long sugar chain.[8] This is required to stabilise the interaction between α-dystroglycan and the extracellular basement membrane. Without these modifications, the glycoprotein cannot anchor the cell which leads to congenital muscular dystrophy (CMD), characterised by severe brain malformations.[15]

O-Galactose (O-Gal)

O-galactose is commonly found on lysine residues in collagen, which often have a hydroxyl group added to form hydroxylysine. Because of this addition of an oxygen, hydroxylysine can then be modified by O-glycosylation. Addition of a galactose to the hydroxyl group is initiated in the endoplasmic reticulum, but occurs predominantly in the Golgi apparatus and only on hydroxylysine residues in a specific sequence.[1][18]

While this O-galactosylation is necessary for correct function in all collagens, it is especially common in collagen types IV and V.[19] In some cases, a glucose sugar can be added to the core galactose.[7]

O-Fucose (O-Fuc)

Addition of fucose sugars to serine and threonine residues is an unusual form of O-glycosylation that occurs in the endoplasmic reticulum and is catalysed by two fucosyltransferases.[20] These were discovered in Plasmodium falciparum [21] and Toxoplasma gondii.[22]

Several different enzymes catalyse the elongation of the core fucose, meaning that different sugars can be added to the initial fucose on the protein.[20] Along with O-glucosylation, O-fucosylation is mainly found on epidermal growth factor (EGF) domains found in proteins.[7] O-fucosylation on EGF domains occurs between the second and third conserved cysteine residues in the protein sequence.[1] Once the core O-fucose has been added, it is often elongated by addition of GlcNAc, galactose and sialic acid.

Notch is an important protein in development, with several EGF domains that are O-fucosylated.[23] Changes in the elaboration of the core fucose determine what interactions the protein can form, and therefore which genes will be transcribed during development. O-fucosylation might also play a role in protein breakdown in the liver.[1]

O-Glucose (O-Glc)

Similarly to O-fucosylation, O-glucosylation is an unusual O-linked modification as it occurs in the endoplasmic reticulum, catalysed by O-glucosyltransferases, and also requires a defined sequence in order to be added to the protein. O-glucose is often attached to serine residues between the first and second conserved cysteine residues of EGF domains, for example in clotting factors VII and IX.[7] O-glucosylation also appears to be necessary for the proper folding of EGF domains in the Notch protein.[24]

Proteoglycans

Structures of heparan sulphate and keratan sulphate, formed by the addition of xylose or GalNAc sugars, respectively, onto serine and threonine residues of proteins.

Proteoglycans consist of a protein with one or more sugar side chains, known as glycosaminoglycans (GAGs), attached to the oxygen of serine and threonine residues.[25] GAGs consist of long chains of repeating sugar units. Proteoglycans are usually found on the cell surface and in the extracellular matrix (ECM), and are important for the strength and flexibility of cartilage and tendons. Absence of proteoglycans is associated with heart and respiratory failure, defects in skeletal development and increased tumor metastasis.[25]

Different types of proteoglycans exist, depending on the sugar that is linked to the oxygen atom of the residue in the protein. For example, the GAG heparan sulphate is attached to a protein serine residue through a xylose sugar.[7] The structure is extended with several N-acetyllactosamine repeating sugar units added onto the xylose. This process is unusual and requires specific xylosyltransferases.[6] Keratan sulphate attaches to a serine or threonine residue through GalNAc, and is extended with two galactose sugars, followed by repeating units of glucuronic acid (GlcA) and GlcNAc. Type II keratan sulphate is especially common in cartilage.[25]

Lipids

Structure of ceramide, galactosylceramide and glucosylceramide.

Galactose or glucose sugars can be attached to a hydroxyl group of ceramide lipids in a different form of O-glycosylation, as it does not occur on proteins.[6] This forms glycosphingolipids, which are important for the localisation of receptors in membranes.[8] Incorrect breakdown of these lipids leads to a group of diseases known as sphingolipidoses, which are often characterised by neurodegeneration and developmental disabilities.

Because both galactose and glucose sugars can be added to the ceramide lipid, we have two groups of glycosphingolipids. Galactosphingolipids are generally very simple in structure and the core galactose is not usually modified. Glucosphingolipids, however, are often modified and can become a lot more complex.

Biosynthesis of galacto- and glucosphingolipids occurs differently.[6] Glucose is added onto ceramide from its precursor in the endoplasmic reticulum, before further modifications occur in the Golgi apparatus.[8] Galactose, on the other hand, is added to ceramide already in the Golgi apparatus, where the galactosphingolipid formed is often sulfated by addition of sulfate groups.[6]

Glycogenin

One of the first and only examples of O-glycosylation on tyrosine, rather than on serine or threonine residues, is the addition of glucose to a tyrosine residue in glycogenin.[7] Glycogenin is a glycosyltransferase that initiates the conversion of glucose to glycogen, present in muscle and liver cells.[26]

Clinical significance

All forms of O-glycosylation are abundant throughout the body and play important roles in many cellular functions.

Lewis epitopes are important in determining blood groups, and allow the generation of an immune response if we detect foreign organs. Understanding them is important in organ transplants.[1]

Hinge regions of immunoglobulins contain highly O-glycosylated regions between individual domains to maintain their structure, allow interactions with foreign antigens and protect the region from proteolytic cleavage.[1][8]

Alzheimer’s may be affected by O-glycosylation. Tau, the protein that accumulates to cause neurodegeneration in Alzheimer’s, contains O-GlcNAc modifications which may be implicated in disease progression.[1]

Changes in O-glycosylation are extremely common in cancer. O-glycan structures, and especially the terminal Lewis epitopes, are important in allowing tumor cells to invade new tissues during metastasis.[6] Understanding these changes in O-glycosylation of cancer cells can lead to new diagnostic approaches and therapeutic opportunities.[1]

See also

References

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  • GlycoEP: In silico Platform for Prediction of N-, O- and C-Glycosites in Eukaryotic Protein Sequences
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