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Difference between revisions of "Glycoside Hydrolase Family 73"

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* [[Author]]: ^^^Florence Vincent^^^
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* [[Responsible Curator]]:  [[User:Bernard Henrissat|Bernard Henrissat]]
 
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|-
 
|-
 
|'''Mechanism'''
 
|'''Mechanism'''
|not known
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|Inverting and Neighboring group participation
 
|-
 
|-
 
|'''Active site residues'''
 
|'''Active site residues'''
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== Substrate specificities ==
 
== Substrate specificities ==
The GH73 family is comprised of bacterial or prokaryotic viral members. Most of the enzymes of this family are peptidoglycan hydrolases that cleave the β-1,4-glycosidic linkage between N-acetylglucosaminyl (NAG) and N-acetylmuramyl (NAM) moieties in the carbohydrate backbone of bacterial peptidoglycan. Because of their cleavage specificity, they are commonly described as N-acetylglucosaminidases.
+
[[Image:Diapositive1recadree.jpg|thumb|500px|right|'''Figure 1.''' Examples of modular GH73 enzymes: SLH: S‐layer homology domains; [[CBM50]]: [[Carbohydrate Binding Module Family 50]]; purple: signal peptide; grey and red: unknown repeated domains. GenBank accession
The activity of the GH73 is mainly focused in daughter cell separation during vegetative growth and it is very often involved in the hydrolysis of the septum after cell division (Acp from ''Clostridium Perfringens'' <cite>Camiade2010</cite> AltA from ''Enterococcus faecalis'' <cite>Eckert2006</cite>). Only ''Listeria monocytogene'' uses Auto as a virulence-associated peptidoglycan hydrolase for host-cell invasion <cite>Bublitz2009</cite>.
+
numbers are indicated for each protein.]]
The GH73 are mostly surface located and exhibit repeated sequences that could be involved in cell-wall binding and therefore reinforce the enzymes catalytic activity. Unknown repeated domains are appended for instance to LytD and LytG from ''Bacillus subtilis'' <cite>Rashid1995 Horsburgh2003</cite>, AcmB from ''Lactococcus lactis'' <cite>Huard2003</cite> and Auto from ''L. monocytogene'' <cite>Bublitz2009</cite>. Some of these repeated domains have been identified like CBM50 also known as LysM domain appended to AcmA for Lactococcus lactis <cite>Inagaki2009</cite>, AltA from ''Enterococcus faecalis'' <cite>Eckert2006</cite> and Mur2-Mur2 from ''Enterococcus hirae'' <cite>Eckert2007</cite>.
+
Family GH73 contains bacterial and viral [[glycoside hydrolase]]s. Most of the enzymes of this family cleave the β-1,4-glycosidic linkage between ''N''-acetylglucosaminyl (NAG) and ''N''-acetylmuramyl (NAM) moieties in the carbohydrate backbone of bacterial peptidoglycans. Because of their cleavage specificity, they are commonly described as β-''N''-acetylglucosaminidases. The enzymes from family GH73 are mainly involved in daughter cell separation during vegetative growth, and they often hydrolyze the septum after cell division (Acp from ''Clostridium perfringens'' <cite>Camiade2010</cite>, AltA from ''Enterococcus faecalis'' <cite>Eckert2006</cite>). Occasionally GH73 enzymes are used during host-cell invasion such as the virulence-associated peptidoglycan hydrolase Auto from ''Listeria monocytogenes'' <cite>Bublitz2009</cite>.
 +
 
 +
GH73 enzymes are mostly surface-located and often exhibit repeated sequences that could be involved in bacterial cell-wall binding (figure 1). Unknown repeated domains are appended for instance to LytD and LytG from ''Bacillus subtilis'' <cite>Rashid1995 Horsburgh2003</cite>, AcmB from ''Lactococcus lactis'' <cite>Huard2003</cite>, and Auto from ''L. monocytogene'' <cite>Bublitz2009</cite>. Some of these repeated domains have been identified such as the carbohydrate-binding modules of family [[CBM50]] (also known as LysM domains) appended for instance to AcmA of ''Lactococcus lactis'' <cite>Inagaki2009</cite>, AltA from ''Enterococcus faecalis'' <cite>Eckert2006</cite> and Mur2-Mur2 from ''Enterococcus hirae'' <cite>Eckert2007</cite>.
  
 
== Kinetics and Mechanism ==
 
== Kinetics and Mechanism ==
No kinetic parameters have been determined for any enzyme of the GH73 family, as the production of synthetic peptidoglycan substrates remains a challenging task.
+
No kinetic parameters have been determined for any enzyme of the GH73 family, as the production of synthetic peptidoglycan substrates remains a challenge.
 +
 
 +
== Three-dimensional structures ==
 +
[[Image:auto-flgjSURFnew.jpg|thumb|300px|right|'''Figure 2.''' Ribbon diagram of Auto structure (orange) and its surface, superimposed on FlgJ structure (green).]]
 +
Crystal structures of GH73 are available and have been reported simultaneously, namely FlgJ from ''Sphingomonas sp.'' (SPH1045-C) <cite>Hashimoto2009</cite> and Auto a virulence associated peptigoglycan hydrolase from ''Listeria monocytogenes'' <cite>Bublitz2009</cite>. The two GH73 show the same fold, with two subdomains consisting of a β-lobe and an α-lobe that together create an extended substrate binding groove (Figure 2). With a typical lysozyme (α+β) fold, the catalytic domain of Auto is structurally related to the catalytic domain of Slt70 from ''E. coli'' <cite>vanAsselt1999</cite>, the family [[GH19]] chitinases and goose egg-white lysozyme (GEWL, [[GH23]]) <cite>Weaver1995</cite>. FlgJ is structurally related to a peptidoglycan degrading enzyme from the bacteriophage phi 29 <cite>Xiang2008</cite> and also to family [[GH22]] and [[GH23]] lysozymes.
  
 
== Catalytic Residues ==
 
== Catalytic Residues ==
 +
[[File: FigurePourCazypedia2022.jpg|thumb|300px|right|'''Figure 3.''' The motion performed by the β-hairpin to close on the active site is shown by comparing FlgJSt, Auto, and AtlA β-hairpin’s positions]] The catalytic [[general acid]] is a glutamate, strictly conserved in the GH73 family. Its catalytic role has been evidenced in FlgJ <cite>Maruyama2010</cite>, Auto <cite>Bublitz2009</cite>, AcmA <cite>Inagaki2009</cite> and AltWN <cite>Yokoi2008</cite>. Glu185 in FlgJ  and Glu122 in Auto have also been identified through structural comparison with the actives sites of [[GH19]], [[GH22]] and [[GH23]] enzymes <cite>Hashimoto2009 Bublitz2009 </cite>.  However, in contrast to [[GH22]] lysozymes, the structures of FlgJ and Auto both lack a nearby second catalytic carboxylate such as Asp52 in hen egg white lysozyme (HEWL), which represents the [[catalytic nucleophile]] <cite>Vocadlo2001</cite>. Interestingly this amino acid is strictly conserved in the sequences of GH73 enzymes but it is situated 13Å away from the Glu [[general acid]] in the active site. Recent work on AtlA from ''Enterococcus faecalis'' identifies key conserved catalytic residues and together with a closed conformation of the active site groove confirms the ([[inverting mechanism]])<cite>Roig-Zamboni2022</cite> (see figure 3).
  
The catalytic proton donor is a Glutamate, strickly conserved in the GH73 family. Its catalytic role has been evidenced in FlgJ <cite>Maruyama2010</cite>, Auto <cite>Bublitz2009</cite>, AcmA <cite>Inagaki2009</cite> and AltWN <cite>Yokoi2008</cite>. Glu185 in FlgJ  and Glu122 in Auto have also been identified through structural comparison with the actives sites from GH23, GH22 and GH19 enzymes <cite>Hashimoto2009 Bublitz2009 </cite>.  Nevertheless, both structures of FlgJ and Auto have in common the evident lack of a nearby second catalytic carboxylate, provided for instance by Asp52(53) in GH22 lysozymes (see figure 2). In FlgJ and Auto the nucleophile/base, a Glu corresponding to Aps52, is strickly conserved in the GH73 family but takes place 13Å far from the Glu proton donor in the active site.[[Image:GH73activesite.jpg|thumb|left|'''Figure 1.''' Comparison of Auto (in yellow) and HEWL (in grey) active sites. Catalytic residues are in italic for HEWL ([[GH22]])]]
+
On the other hand, significant residual activity was found when the putative nucleophile/base residue of  AcmA and AltWN were converted to glutamine or asparagine (for Asp1275 in AltWN), which is more compatible with substrate-assisted catalysis (also termed "[[neighboring group participation]]" mechanism) involving anchimeric assistance by the acetamido group of the GlcNAc moiety. In such a mechanism, a neighboring tyrosine is frequently involved. In family GH73, a Tyr residue is highly conserved (Fig2: Tyr220 in Auto), in close proximity to the catalytic [[general acid]] Glu. Substitution of this Tyr residue in FlgJ, AcmA and AltWN was associated with a reduced activity similar to that resulting from the mutation of the [[general acid]] Glu <cite>Maruyama2010 Inagaki2009 Yokoi2008</cite>. The [[neighboring group participation]] mechanism involving the [[general acid]] Glu and the Tyr as essential catalytic residues found support from the sequence comparison of family GH73 with families [[GH20]], [[GH18]], [[GH23]] and [[GH56]], which do not have a catalytic nucleophile residue <cite>Inagaki2009</cite>.
 
 
Mutational analysis on the putative distant nucleophile (Glu156) in Auto, showed a drastic decrease of the catalytic activity <cite>Bublitz2009</cite>. Therefore, Bublitz et al proposed a single displacement mechanism involving a distant carboxylate that would serve as a base assisting a water molecule for the nucleophilic attack on the opposite side of the sugar ring ([[inverting mechanism]]). This mechanism also involves an important displacement on the β-lobe upon substrat binding that would bring the nucleophile/base closer to the active site.
 
 
 
On the other hand, mutational analyses on FlgJ , AcmA and AltWN revealed an uncertainty on the nucleophile/base residue and the putative existence of another key catalytic residue. It is noteworthy that only the mutational analysis on Auto revealed a decreased catalytic activity when the nucleophile Glu156 was mutated into glutamine. In FlgJ, AcmA and AltWN, an important residual activity upon mutation of this equivalent Glu into alanine, glutamine or asparagine (for Asp1275 in AltWN) ruled out this residue as a key catalytic residue.
 
 
 
In close proximity to the Glu proton donor is a Tyrosine highly conserved in the GH73 family (Fig1: Tyr220 in Auto). Amino acid substitution of this tyrosine on FlgJ, AcmA and AltWN exhibited reduced activity similar to the mutation of the Glu proton donor <cite>Maruyama2010</cite><cite>Inagaki2009</cite><cite>Yokoi2008</cite>. The substitution of this Tyr into a Phe or Trp, in AcmA and AltWN, retained substantial activity.
 
 
 
Inagaki and Murayama agreed on the fact that the Glu proton donor and this nearby Tyr  are probably crucial for enzyme activities of FlgJ, AcmA, and AltWN. The role of the Tyr have already been discussed for Auto, they suggested the need for an hydrophobic residue in this position, to protonate the carboxylate group of the proton donor and maintain the stable conformation of the active site residues <cite>Bublitz2009</cite>.
 
 
 
Finally, based on sequence analyses in the GH73 family and in comparison with families GH20, GH18, GH23 and GH56, that don't have a catalytic nucleophile residue. Inagaki et al suggested a [[Neighboring group participation]] involving the Glu proton donor and the Tyr as essential catalytic residues. This mechanism implies that the 2-acetamido group of the NAG is acting as an intramolecular nucleophile <cite>Inagaki2009</cite>.
 
 
 
== Three-dimensional structures ==
 
[[Image:auto-flgjSURFnew.jpg|thumb|right|'''Figure 2.''' Ribbon diagram of Auto structure (orange) and its surface, superimposed on FlgJ structure (green).]]
 
 
 
Crystal structures of GH73 are available and have been coincidently reported, FlgJ from ''Sphingomonas sp.'' (SPH1045-C) <cite>Hashimoto2009</cite> and Auto a virulence associated peptigoglycan hydrolase from ''Listeria monocytogenes'' <cite>Bublitz2009</cite>. A structure for a catalytic mutant (E185A) of FlgJ has been solved by Maruyama et al <cite>Maruyama2010</cite> but doesn’t show any conformational changes. The two GH73 show the same fold, with two subdomains consisting of a β-lobe and an α-lobe that together create an extended substrate binding groove (Figure 2). With a typical lysozyme (α+β) fold, the catalytic domain of Auto is structurally related to the catalytic domain of Slt70 from ''E. coli'' <cite>vanAsselt1999</cite>, the family [[GH19]] chitinases and goose egg-white lysozyme (GEWL, [[GH23]])<cite>Weaver1995</cite>. FlgJ is structurally related to a peptidoglycan degrading enzyme from the bacteriophage phi 29 <cite>Xiang2008</cite> and also to family [[GH22]] and [[GH23]] lysozymes.
 
  
 
== Family Firsts ==
 
== Family Firsts ==
;First stereochemistry determination:
+
;First [[general acid/base]]/[[general acid]] residue identification: Glu 1238 in AltWN from ''Staphylococcus warneri'' M <cite>Yokoi2008</cite>
;First catalytic nucleophile identification: Evidence for a putative nucleophile residue in Auto, a peptidoglycan hydrolase from ''Lytseria monocytogene'' <cite>Bublitz2009</cite>
 
;First general acid/base residue identification:
 
 
;First 3-D structure: peptidoglycan hydrolase FlgJ from ''Sphingomonas sp.'' <cite>Hashimoto2009</cite>
 
;First 3-D structure: peptidoglycan hydrolase FlgJ from ''Sphingomonas sp.'' <cite>Hashimoto2009</cite>
  
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#Weaver1995 pmid=7823320
 
#Weaver1995 pmid=7823320
 
#Xiang2008 pmid=18606992
 
#Xiang2008 pmid=18606992
 +
#Vocadlo2001 pmid=11518970
 +
 +
#Roig-Zamboni2022 pmid=35398351
 
</biblio>
 
</biblio>
  
 
[[Category:Glycoside Hydrolase Families|GH073]]
 
[[Category:Glycoside Hydrolase Families|GH073]]

Latest revision as of 03:48, 27 December 2022

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Glycoside Hydrolase Family GH73
Clan none, α+β "lysozyme fold"
Mechanism Inverting and Neighboring group participation
Active site residues partially known
CAZy DB link
https://www.cazy.org/GH73.html

Substrate specificities

Figure 1. Examples of modular GH73 enzymes: SLH: S‐layer homology domains; CBM50: Carbohydrate Binding Module Family 50; purple: signal peptide; grey and red: unknown repeated domains. GenBank accession numbers are indicated for each protein.

Family GH73 contains bacterial and viral glycoside hydrolases. Most of the enzymes of this family cleave the β-1,4-glycosidic linkage between N-acetylglucosaminyl (NAG) and N-acetylmuramyl (NAM) moieties in the carbohydrate backbone of bacterial peptidoglycans. Because of their cleavage specificity, they are commonly described as β-N-acetylglucosaminidases. The enzymes from family GH73 are mainly involved in daughter cell separation during vegetative growth, and they often hydrolyze the septum after cell division (Acp from Clostridium perfringens [1], AltA from Enterococcus faecalis [2]). Occasionally GH73 enzymes are used during host-cell invasion such as the virulence-associated peptidoglycan hydrolase Auto from Listeria monocytogenes [3].

GH73 enzymes are mostly surface-located and often exhibit repeated sequences that could be involved in bacterial cell-wall binding (figure 1). Unknown repeated domains are appended for instance to LytD and LytG from Bacillus subtilis [4, 5], AcmB from Lactococcus lactis [6], and Auto from L. monocytogene [3]. Some of these repeated domains have been identified such as the carbohydrate-binding modules of family CBM50 (also known as LysM domains) appended for instance to AcmA of Lactococcus lactis [7], AltA from Enterococcus faecalis [2] and Mur2-Mur2 from Enterococcus hirae [8].

Kinetics and Mechanism

No kinetic parameters have been determined for any enzyme of the GH73 family, as the production of synthetic peptidoglycan substrates remains a challenge.

Three-dimensional structures

Figure 2. Ribbon diagram of Auto structure (orange) and its surface, superimposed on FlgJ structure (green).

Crystal structures of GH73 are available and have been reported simultaneously, namely FlgJ from Sphingomonas sp. (SPH1045-C) [9] and Auto a virulence associated peptigoglycan hydrolase from Listeria monocytogenes [3]. The two GH73 show the same fold, with two subdomains consisting of a β-lobe and an α-lobe that together create an extended substrate binding groove (Figure 2). With a typical lysozyme (α+β) fold, the catalytic domain of Auto is structurally related to the catalytic domain of Slt70 from E. coli [10], the family GH19 chitinases and goose egg-white lysozyme (GEWL, GH23) [11]. FlgJ is structurally related to a peptidoglycan degrading enzyme from the bacteriophage phi 29 [12] and also to family GH22 and GH23 lysozymes.

Catalytic Residues

Figure 3. The motion performed by the β-hairpin to close on the active site is shown by comparing FlgJSt, Auto, and AtlA β-hairpin’s positions

The catalytic general acid is a glutamate, strictly conserved in the GH73 family. Its catalytic role has been evidenced in FlgJ [13], Auto [3], AcmA [7] and AltWN [14]. Glu185 in FlgJ and Glu122 in Auto have also been identified through structural comparison with the actives sites of GH19, GH22 and GH23 enzymes [3, 9]. However, in contrast to GH22 lysozymes, the structures of FlgJ and Auto both lack a nearby second catalytic carboxylate such as Asp52 in hen egg white lysozyme (HEWL), which represents the catalytic nucleophile [15]. Interestingly this amino acid is strictly conserved in the sequences of GH73 enzymes but it is situated 13Å away from the Glu general acid in the active site. Recent work on AtlA from Enterococcus faecalis identifies key conserved catalytic residues and together with a closed conformation of the active site groove confirms the (inverting mechanism)[16] (see figure 3).

On the other hand, significant residual activity was found when the putative nucleophile/base residue of AcmA and AltWN were converted to glutamine or asparagine (for Asp1275 in AltWN), which is more compatible with substrate-assisted catalysis (also termed "neighboring group participation" mechanism) involving anchimeric assistance by the acetamido group of the GlcNAc moiety. In such a mechanism, a neighboring tyrosine is frequently involved. In family GH73, a Tyr residue is highly conserved (Fig2: Tyr220 in Auto), in close proximity to the catalytic general acid Glu. Substitution of this Tyr residue in FlgJ, AcmA and AltWN was associated with a reduced activity similar to that resulting from the mutation of the general acid Glu [7, 13, 14]. The neighboring group participation mechanism involving the general acid Glu and the Tyr as essential catalytic residues found support from the sequence comparison of family GH73 with families GH20, GH18, GH23 and GH56, which do not have a catalytic nucleophile residue [7].

Family Firsts

First general acid/base/general acid residue identification
Glu 1238 in AltWN from Staphylococcus warneri M [14]
First 3-D structure
peptidoglycan hydrolase FlgJ from Sphingomonas sp. [9]

References

  1. Camiade E, Peltier J, Bourgeois I, Couture-Tosi E, Courtin P, Antunes A, Chapot-Chartier MP, Dupuy B, and Pons JL. (2010). Characterization of Acp, a peptidoglycan hydrolase of Clostridium perfringens with N-acetylglucosaminidase activity that is implicated in cell separation and stress-induced autolysis. J Bacteriol. 2010;192(9):2373-84. DOI:10.1128/JB.01546-09 | PubMed ID:20190047 [Camiade2010]
  2. Eckert C, Lecerf M, Dubost L, Arthur M, and Mesnage S. (2006). Functional analysis of AtlA, the major N-acetylglucosaminidase of Enterococcus faecalis. J Bacteriol. 2006;188(24):8513-9. DOI:10.1128/JB.01145-06 | PubMed ID:17041059 [Eckert2006]
  3. Bublitz M, Polle L, Holland C, Heinz DW, Nimtz M, and Schubert WD. (2009). Structural basis for autoinhibition and activation of Auto, a virulence-associated peptidoglycan hydrolase of Listeria monocytogenes. Mol Microbiol. 2009;71(6):1509-22. DOI:10.1111/j.1365-2958.2009.06619.x | PubMed ID:19210622 [Bublitz2009]
  4. Rashid MH, Mori M, and Sekiguchi J. (1995). Glucosaminidase of Bacillus subtilis: cloning, regulation, primary structure and biochemical characterization. Microbiology (Reading). 1995;141 ( Pt 10):2391-404. DOI:10.1099/13500872-141-10-2391 | PubMed ID:7581999 [Rashid1995]
  5. Horsburgh GJ, Atrih A, Williamson MP, and Foster SJ. (2003). LytG of Bacillus subtilis is a novel peptidoglycan hydrolase: the major active glucosaminidase. Biochemistry. 2003;42(2):257-64. DOI:10.1021/bi020498c | PubMed ID:12525152 [Horsburgh2003]
  6. Huard C, Miranda G, Wessner F, Bolotin A, Hansen J, Foster SJ, and Chapot-Chartier MP. (2003). Characterization of AcmB, an N-acetylglucosaminidase autolysin from Lactococcus lactis. Microbiology (Reading). 2003;149(Pt 3):695-705. DOI:10.1099/mic.0.25875-0 | PubMed ID:12634338 [Huard2003]
  7. Inagaki N, Iguchi A, Yokoyama T, Yokoi KJ, Ono Y, Yamakawa A, Taketo A, and Kodaira K. (2009). Molecular properties of the glucosaminidase AcmA from Lactococcus lactis MG1363: mutational and biochemical analyses. Gene. 2009;447(2):61-71. DOI:10.1016/j.gene.2009.08.004 | PubMed ID:19686822 [Inagaki2009]
  8. Eckert C, Magnet S, and Mesnage S. (2007). The Enterococcus hirae Mur-2 enzyme displays N-acetylglucosaminidase activity. FEBS Lett. 2007;581(4):693-6. DOI:10.1016/j.febslet.2007.01.033 | PubMed ID:17258207 [Eckert2007]
  9. Hashimoto W, Ochiai A, Momma K, Itoh T, Mikami B, Maruyama Y, and Murata K. (2009). Crystal structure of the glycosidase family 73 peptidoglycan hydrolase FlgJ. Biochem Biophys Res Commun. 2009;381(1):16-21. DOI:10.1016/j.bbrc.2009.01.186 | PubMed ID:19351587 [Hashimoto2009]
  10. van Asselt EJ, Thunnissen AM, and Dijkstra BW. (1999). High resolution crystal structures of the Escherichia coli lytic transglycosylase Slt70 and its complex with a peptidoglycan fragment. J Mol Biol. 1999;291(4):877-98. DOI:10.1006/jmbi.1999.3013 | PubMed ID:10452894 [vanAsselt1999]
  11. Weaver LH, Grütter MG, and Matthews BW. (1995). The refined structures of goose lysozyme and its complex with a bound trisaccharide show that the "goose-type" lysozymes lack a catalytic aspartate residue. J Mol Biol. 1995;245(1):54-68. DOI:10.1016/s0022-2836(95)80038-7 | PubMed ID:7823320 [Weaver1995]
  12. Xiang Y, Morais MC, Cohen DN, Bowman VD, Anderson DL, and Rossmann MG. (2008). Crystal and cryoEM structural studies of a cell wall degrading enzyme in the bacteriophage phi29 tail. Proc Natl Acad Sci U S A. 2008;105(28):9552-7. DOI:10.1073/pnas.0803787105 | PubMed ID:18606992 [Xiang2008]
  13. Maruyama Y, Ochiai A, Itoh T, Mikami B, Hashimoto W, and Murata K. (2010). Mutational studies of the peptidoglycan hydrolase FlgJ of Sphingomonas sp. strain A1. J Basic Microbiol. 2010;50(4):311-7. DOI:10.1002/jobm.200900249 | PubMed ID:20586063 [Maruyama2010]
  14. Yokoi KJ, Sugahara K, Iguchi A, Nishitani G, Ikeda M, Shimada T, Inagaki N, Yamakawa A, Taketo A, and Kodaira K. (2008). Molecular properties of the putative autolysin Atl(WM) encoded by Staphylococcus warneri M: mutational and biochemical analyses of the amidase and glucosaminidase domains. Gene. 2008;416(1-2):66-76. DOI:10.1016/j.gene.2008.03.004 | PubMed ID:18440165 [Yokoi2008]
  15. Vocadlo DJ, Davies GJ, Laine R, and Withers SG. (2001). Catalysis by hen egg-white lysozyme proceeds via a covalent intermediate. Nature. 2001;412(6849):835-8. DOI:10.1038/35090602 | PubMed ID:11518970 [Vocadlo2001]
  16. Roig-Zamboni V, Barelier S, Dixon R, Galley NF, Ghanem A, Nguyen QP, Cahuzac H, Salamaga B, Davis PJ, Bourne Y, Mesnage S, and Vincent F. (2022). Molecular basis for substrate recognition and septum cleavage by AtlA, the major N-acetylglucosaminidase of Enterococcus faecalis. J Biol Chem. 2022;298(5):101915. DOI:10.1016/j.jbc.2022.101915 | PubMed ID:35398351 [Roig-Zamboni2022]

All Medline abstracts: PubMed