Difference between revisions of "Glycosyltransferase Family 138"

Latest revision as of 20:45, 4 December 2025

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Glycosyltransferase Family GT138
Clan	Fido fold
Mechanism	Inverting
Active site residues	Known
CAZy DB link
https://www.cazy.org/GT138.html

Substrate specificities

GT138 family of glycosyltransferase is exemplified by AvrB, a Fido protein (Fig. 1A) [1]. As a bacterial effector from the plant pathogen Pseudomonas syringae, AvrB utilizes host UDP-rhamnose (or dTDP-rhamnose in vitro) as a co-substrate to modify the host protein RIN4 and causes the programmed cell death (namely hypersensitive response) [1, 2].

Kinetics and Mechanism

AvrB contains a Fido domain [3, 4] (Fig. 1A), different from other known glycosyltransferases containing folds of GT-A, GT-B, GT-C, lysozyme-type, GT101, and GT108 [5, 6, 7, 8] (Fig. 1B). Interestingly, Fido proteins can also be enzymes with activities of AMPylation [9], phosphorylation [10], UMPylation [11], and phosphocholination [12, 13]. Hence, AvrB is a unique Fido protein that functions as a glycosyltransferase.

Figure 1. Glycosyltransferase folds. (A) Fido fold (left []) is found in diverse enzymes including AvrB (right), which is a distinct glycosyltransferase. (B) Other known glycosyltransferases contain folds of GT-A, GT-B, GT-C, lysozyme-type, GT101, and GT108. PDB codes are provided for representative structures.

The rhamnosylation reaction catalyzed by AvrB does not require divalent cations (e.g., Mg²⁺) [1]. In the reaction, rhamnose is directly transferred to the side chain of a threonine of RIN4, T166 (Fig. 2) [1].

Figure 2. Catalysis mechanisms for RIN4 rhamnosylation by AvrB supported by crystal structures [1]. (A) AvrB bound with RIN4. (B) UDP-rhamnose bound with AvrB and RIN4. (C) Rhamnose transferred to T166 of RIN4. (D) Release of rhamnosylated RIN4.

Catalytic Residues

A threonine (T166) from the protein substrate directly attacks the rhamnose moiety in the co-substrate, UDP-rhamnose (Fig. 2) [1]. The threonine is close to a histidine and a threonine in AvrB, which may stabilize the acceptor. UDP-rhamnose is stabilized by a few residues in the pocket (Fig. 2) [1].

Three-dimensional structures

AvrB represents the prototype for glycosyltransferases of Fido fold. AvrB contains a large internal domain between helix α2 and helix α3 (Fig. 1A) [1, 3, 4, 14]. AvrB shares similar structural features with other Fido proteins despite the primary sequences are divergent [4].

Family Firsts

The first member of GT138 family shown to be a glycosyltransferase is AvrB [1].

The first structure of GT138 family is AvrB [3]. A few AvrB structures are available to reveal the catalysis mechanisms [1, 3, 14]

References

All Medline abstracts: PubMed

@@ Line 12: / Line 12: @@
 |-
 |'''Clan'''
-|Fido
+|Fido fold
 |-
 |'''Mechanism'''
@@ Line 29: / Line 29: @@
 == Substrate specificities ==
-Content is to be added here.
+'''GT138''' family of glycosyltransferase is exemplified by '''AvrB''', a Fido protein (Fig. 1A) <cite>Peng2024</cite>. As a bacterial effector from the plant pathogen ''Pseudomonas syringae'', '''AvrB utilizes host UDP-rhamnose''' '''(or dTDP-rhamnose ''in vitro'')''' '''as a co-substrate to modify the host protein RIN4''' and causes the programmed cell death (namely hypersensitive response) <cite>Peng2024, Mackey2002</cite>.
-Authors may get an idea of what to put in each field from ''Curator Approved'' [[Glycosyltransferase Families]]. ''(TIP: Right click with your mouse and open this link in a new browser window...)''
-In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>.
 == Kinetics and Mechanism ==
-Content is to be added here.
+AvrB contains a '''Fido''' domain <cite>Lee2004, Kinch2009</cite> (Fig. 1A), different from other known glycosyltransferases containing folds of GT-A, GT-B, GT-C, lysozyme-type, GT101, and GT108 <cite>Varki2022, Lairson2008, Zhang2014, Sernee2019</cite> (Fig. 1B). Interestingly, Fido proteins can also be enzymes with activities of AMPylation <cite>Yarbrough2009</cite>, phosphorylation <cite>Castro-Roa2013</cite>, UMPylation <cite>Feng2012</cite>, and phosphocholination <cite>Mukherjee2011, Campanacci2013</cite>. Hence, AvrB is a unique Fido protein that functions as a glycosyltransferase.
+[[File:GT138-Fig1-V3.png|thumb|1300px|right|'''Figure 1. Glycosyltransferase folds.''' ('''A''') Fido fold (left <cite>Kinch2009</cite>) is found in diverse enzymes including AvrB (right), which is a distinct glycosyltransferase. ('''B''') Other known glycosyltransferases contain folds of GT-A, GT-B, GT-C, lysozyme-type, GT101, and GT108. PDB codes are provided for representative structures.]]
+The rhamnosylation reaction catalyzed by AvrB does not require divalent cations (e.g., Mg<sup>2+</sup>) <cite>Peng2024</cite>. In the reaction, rhamnose is directly transferred to the side chain of a threonine of RIN4, T166 (Fig. 2) <cite>Peng2024</cite>.
+[[File:GT138-figure-2.png|thumb|900px|center|'''Figure 2. Catalysis mechanisms for RIN4 rhamnosylation by AvrB supported by crystal structures <cite>Peng2024</cite>.''' ('''A''') AvrB bound with RIN4. ('''B''') UDP-rhamnose bound with AvrB and RIN4. ('''C''') Rhamnose transferred to T166 of RIN4. ('''D''') Release of rhamnosylated RIN4.]]
 == Catalytic Residues ==
-Content is to be added here.
+A threonine (T166) from the protein substrate directly attacks the rhamnose moiety in the co-substrate, UDP-rhamnose (Fig. 2) <cite>Peng2024</cite>. The threonine is close to a histidine and a threonine in AvrB, which may stabilize the acceptor. UDP-rhamnose is stabilized by a few residues in the pocket (Fig. 2) <cite>Peng2024</cite>.
 == Three-dimensional structures ==
-Content is to be added here.
+AvrB represents the prototype for glycosyltransferases of Fido fold. AvrB contains a large internal domain between helix α2 and helix α3 (Fig. 1A) <cite>Lee2004, Desveaux2007, Kinch2009, Peng2024</cite>. AvrB shares similar structural features with other Fido proteins despite the primary sequences are divergent <cite>Kinch2009</cite>.
 == Family Firsts ==
-;First stereochemistry determination: Content is to be added here.
+The first member of GT138 family shown to be a glycosyltransferase is AvrB <cite>Peng2024</cite>.
-;First catalytic nucleophile identification: Content is to be added here.
-;First general acid/base residue identification: Content is to be added here.
+The first structure of GT138 family is AvrB <cite>Lee2004</cite>. A few AvrB structures are available to reveal the catalysis mechanisms <cite>Lee2004, Desveaux2007, Peng2024</cite>
-;First 3-D structure: Content is to be added here.
 == References ==
 <biblio>
-#Cantarel2009 pmid=18838391
-#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].
+#Peng2024 pmid=38354245
+#Kinch2009 pmid=19503829
+#Yarbrough2009 pmid=19039103
+#Castro-Roa2013 pmid=24141193
+#Feng2012 pmid=22504181
+#Mukherjee2011 pmid=21822290
+#Campanacci2013 pmid=23572077
+#Varki2022 pmid=35536922
+#Lairson2008 pmid=18518825
+#Zhang2014 pmid=25023666
+#Sernee2019 pmid=31513773
+#Mackey2002 pmid=11955429
+#Lee2004 pmid=15016364
+#Desveaux2007 pmid=17397263
 </biblio>
 <!-- Do not delete this Category tag -->
 [[Category:Glycosyltransferase Families|GT138]]