Structural studies of the retaining galactosyltransferase LGTC from Neisseria meningitidis

“…The notion that α-retaining glycosyl transfer catalysed by phosphorylases and nucleotide-dependent GTs could occur generally without the requirement for a covalent β-glycosyl-enzyme intermediate [30] has gained considerable support from the recent X-ray structures of maltodextrin phosphorylase from Escherichia coli [31] and galactosyltransferase LtgC from Neisseria meningitidis [27] in complexes with donor and acceptor analogues. Inspection of the active sites of both enzymes revealed clearly that no carboxylate group is placed into position as a candidate catalytic nucleophile.…”

“…Bivalent metal ions such as Mg# + or Mn# + have been shown to be co-ordinated to two oxygen atoms from each of the two phosphates in nucleotide diphosphates, and interact with an acidic amino acid, usually an aspartate from a widely conserved Asp-Xaa-Asp motif [27,[36][37][38]. Water molecules complete the co-ordination sphere of the metal ion.…”

“…Inspection of the active sites of both enzymes revealed clearly that no carboxylate group is placed into position as a candidate catalytic nucleophile. Since evidence for a doubledisplacement mechanism has remained elusive for maltodextrin phosphorylase and galactosyltransferase, alternative mechanistic scenarios have been proposed [11,12,15,27,30,31]. One of these is the so-called internal return (S N i) mechanism of glycosyl transfer that assumes approach of the nucleophile towards the reactive carbon from the same side from where the leaving group departs [11,32].…”

“…Mg# + (or Mn# + ) may play an important role in the catalytic mechanism of glycosyl transfer catalysed by retaining [27,30] and inverting nucleotide sugar-dependent transferases (reviewed in [36] ; see also [37,38]), which are related to trehalose phosphorylase through family relationships (GT family 4) or general mechanistic similarities (see [11] for a detailed discussion of mechanisms). Bivalent metal ions such as Mg# + or Mn# + have been shown to be co-ordinated to two oxygen atoms from each of the two phosphates in nucleotide diphosphates, and interact with an acidic amino acid, usually an aspartate from a widely conserved Asp-Xaa-Asp motif [27,[36][37][38].…”

“…A few other α-retaining glucosyl transferases are known to utilize sequential kinetic mechanisms that are characterized by the strict requirement for a ternary enzyme-substrate complex : sucrose synthetase (GT family 4) [23,24], glycogen synthetase (GT family 5) [25,26], galactosyltransferase LgtC (GT family 8) [27] and glycogen phosphorylase (GT family 35) [28]. It has been speculated that ternary-complex kinetics could reflect an enzymic mechanism for minimizing the likelihood of the reaction of a glucosyl-enzyme intermediate (or another reactive intermediate) with water and thus catalysing glucosyl transfer with only scant hydrolysis.…”

Fungal trehalose phosphorylase: kinetic mechanism, pH-dependence of the reaction and some structural properties of the enzyme from Schizophyllum commune

“…The notion that α-retaining glycosyl transfer catalysed by phosphorylases and nucleotide-dependent GTs could occur generally without the requirement for a covalent β-glycosyl-enzyme intermediate [30] has gained considerable support from the recent X-ray structures of maltodextrin phosphorylase from Escherichia coli [31] and galactosyltransferase LtgC from Neisseria meningitidis [27] in complexes with donor and acceptor analogues. Inspection of the active sites of both enzymes revealed clearly that no carboxylate group is placed into position as a candidate catalytic nucleophile.…”

“…Bivalent metal ions such as Mg# + or Mn# + have been shown to be co-ordinated to two oxygen atoms from each of the two phosphates in nucleotide diphosphates, and interact with an acidic amino acid, usually an aspartate from a widely conserved Asp-Xaa-Asp motif [27,[36][37][38]. Water molecules complete the co-ordination sphere of the metal ion.…”

“…Inspection of the active sites of both enzymes revealed clearly that no carboxylate group is placed into position as a candidate catalytic nucleophile. Since evidence for a doubledisplacement mechanism has remained elusive for maltodextrin phosphorylase and galactosyltransferase, alternative mechanistic scenarios have been proposed [11,12,15,27,30,31]. One of these is the so-called internal return (S N i) mechanism of glycosyl transfer that assumes approach of the nucleophile towards the reactive carbon from the same side from where the leaving group departs [11,32].…”

“…Mg# + (or Mn# + ) may play an important role in the catalytic mechanism of glycosyl transfer catalysed by retaining [27,30] and inverting nucleotide sugar-dependent transferases (reviewed in [36] ; see also [37,38]), which are related to trehalose phosphorylase through family relationships (GT family 4) or general mechanistic similarities (see [11] for a detailed discussion of mechanisms). Bivalent metal ions such as Mg# + or Mn# + have been shown to be co-ordinated to two oxygen atoms from each of the two phosphates in nucleotide diphosphates, and interact with an acidic amino acid, usually an aspartate from a widely conserved Asp-Xaa-Asp motif [27,[36][37][38].…”

“…A few other α-retaining glucosyl transferases are known to utilize sequential kinetic mechanisms that are characterized by the strict requirement for a ternary enzyme-substrate complex : sucrose synthetase (GT family 4) [23,24], glycogen synthetase (GT family 5) [25,26], galactosyltransferase LgtC (GT family 8) [27] and glycogen phosphorylase (GT family 35) [28]. It has been speculated that ternary-complex kinetics could reflect an enzymic mechanism for minimizing the likelihood of the reaction of a glucosyl-enzyme intermediate (or another reactive intermediate) with water and thus catalysing glucosyl transfer with only scant hydrolysis.…”

Fungal trehalose phosphorylase: kinetic mechanism, pH-dependence of the reaction and some structural properties of the enzyme from Schizophyllum commune

Chemoenzymatic synthesis of 6‐phospho‐cyclophellitol as a novel probe of 6‐phospho‐β‐glucosidases

Glycosyltransferases of the GT8 Family