Glycoside Hydrolase Family 103

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• Author: ^^^Anthony Clarke^^^
• Responsible Curator: ^^^Anthony Clarke^^^

Substrate specificities

Figure 1. Reaction catalyzed by family GH103 enzymes. LT, lytic transglycosylase. (click to enlarge).

The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 3 of the classification scheme of Blackburn and Clarke [1]. The prototype for this family is membrane-bound lytic transglycosylase B (MltB) from Escherichia coli [2]. These enzymes cleave the β-1,4 linkage between N-acetylmuramoyl and N-acetylglucosaminyl residues in peptidoglycan (Figure 1), No other activities have been observed.

Kinetics and Mechanism

The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end [3]. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (K_M and V_max) parameters have been estimated for Pseudomonas aeruginosa MltB acting on insoluble peptidoglycan sacculi [4].

Catalytic Residues

Figure 2. Reaction mechanism proposed for E. coli MltB. (click to enlarge).

As with other lytic transglycosylases (families GH23, GH102, and GH104), the GH103 enzymes are thought to possess a single catalytic acid/base residue. This residue has been identified as Glu162 in MltB from both E. coli and P. aeruginosa and, indeed, its replacement abolishes catalytic activity [4, 5]. The mechanism of action of family GH103 enzymes has been investigated the most compared to the lytic transglycosylases of the other families (GH23,GH102, and GH104).

Examination of crystal structures of E. coli Slt35 (a soluble proteolytic derivative of MltB)and theoretical considerations led to the proposal of a mechanism that accommodates a single catalytic at its active site. Thus, based on the complexes formed with murodipeptide, chitobiose, and the inhibitor bulgecin, a substrate-assisted mechanism, analogous to the family GH18 chitinases and chitobiases, family GH20 N-acetyl-β-hexosaminidases, and family GH23 lytic transglycosylases, has been invoked [6]. Thus, the catalytic Glu162 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu73 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. The β-hexosaminidase inhibitor NAG-thiazoline was found to inhibit P. aeruginosa MltB thus supporting the proposal for the formation of an oxazolinium ion intermediate [7]

Three-dimensional structures

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Family Firsts

Family Firsts

First identification of lytic transglycosylase

MltA from E. coli [2].

First catalytic nucleophile identification

Not applicable for lytic transglycosylases.

First general acid/base residue identification

Inferred by X-ray crystallography of E. coli MltA [4].

First 3-D structure

E. coli MltA [4].

First identification as a lipoprotein

E. coli MltA [7].

First identification of localization to outer membrane

E. coli MltA [7].

Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins

E. coli MltA [8].

References

1. Blackburn NT and Clarke AJ. (2001). Identification of four families of peptidoglycan lytic transglycosylases. J Mol Evol. 2001;52(1):78-84. DOI:10.1007/s002390010136 | PubMed ID:11139297 [1]
2. Engel H, Smink AJ, van Wijngaarden L, and Keck W. (1992). Murein-metabolizing enzymes from Escherichia coli: existence of a second lytic transglycosylase. J Bacteriol. 1992;174(20):6394-403. DOI:10.1128/jb.174.20.6394-6403.1992 | PubMed ID:1356966 [2]
3. Höltje JV, Mirelman D, Sharon N, and Schwarz U. (1975). Novel type of murein transglycosylase in Escherichia coli. J Bacteriol. 1975;124(3):1067-76. DOI:10.1128/jb.124.3.1067-1076.1975 | PubMed ID:357 [3]
4. Blackburn NT and Clarke AJ. (2002). Characterization of soluble and membrane-bound family 3 lytic transglycosylases from Pseudomonas aeruginosa. Biochemistry. 2002;41(3):1001-13. DOI:10.1021/bi011833k | PubMed ID:11790124 [4]
5. van Asselt EJ, Dijkstra AJ, Kalk KH, Takacs B, Keck W, and Dijkstra BW. (1999). Crystal structure of Escherichia coli lytic transglycosylase Slt35 reveals a lysozyme-like catalytic domain with an EF-hand. Structure. 1999;7(10):1167-80. DOI:10.1016/s0969-2126(00)80051-9 | PubMed ID:10545329 [5]
6. van Asselt EJ, Kalk KH, and Dijkstra BW. (2000). Crystallographic studies of the interactions of Escherichia coli lytic transglycosylase Slt35 with peptidoglycan. Biochemistry. 2000;39(8):1924-34. DOI:10.1021/bi992161p | PubMed ID:10684641 [6]
7. Reid CW, Blackburn NT, Legaree BA, Auzanneau FI, and Clarke AJ. (2004). Inhibition of membrane-bound lytic transglycosylase B by NAG-thiazoline. FEBS Lett. 2004;574(1-3):73-9. DOI:10.1016/j.febslet.2004.08.006 | PubMed ID:15358542 [7]

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All Medline abstracts: PubMed