Converting a β-Glycosidase into a β-Transglycosidase by Directed Evolution

Huang, Feng; Drone, Jullien; Hoffmann, Lionel; Tran, V.H.; Tellier, Charles; Rabiller, Claude; Dion, Michel

doi:10.1074/jbc.m502873200

Cited by 96 publications

(87 citation statements)

References 37 publications

(39 reference statements)

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“…On the other hand, if the situation is similar to some glycosidases, there might be just one mutation necessary to convert the transferase activity into a hydrolysis activity. This was observed for a ␤-glycosidase of Thermus thermophilus, where several single mutations changed the main activity from hydrolysis action to transglycosylation and vice versa (18). Homoserine acetyltransferases play a role in de novo methionine biosynthesis of many bacteria.…”

Section: Discussionmentioning

confidence: 97%

Degradation of Alkyl Methyl Ketones by Pseudomonas veronii MEK700

et al. 2007

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Pseudomonas veronii MEK700 was isolated from a biotrickling filter cleaning 2-butanone-loaded waste air. The strain is able to grow on 2-butanone and 2-hexanol. The genes for degradation of short chain alkyl methyl ketones were identified by transposon mutagenesis using a newly designed transposon, mini-Tn5495, and cloned in Escherichia coli. DNA sequence analysis of a 15-kb fragment revealed three genes involved in methyl ketone degradation. The deduced amino acid sequence of the first gene, mekA, had high similarity to BaeyerVilliger monooxygenases; the protein of the second gene, mekB, had similarity to homoserine acetyltransferases; the third gene, mekR, encoded a putative transcriptional activator of the AraC/XylS family. The three genes were located between two gene groups: one comprising a putative phosphoenolpyruvate synthase and glycogen synthase, and the other eight genes for the subunits of an ATPase. Inactivation of mekA and mekB by insertion of the mini-transposon abolished growth of P. veronii MEK700 on 2-butanone and 2-hexanol. The involvement of mekR in methyl ketone degradation was observed by heterologous expression of mekA and mekB in Pseudomonas putida. A fragment containing mekA and mekB on a plasmid was not sufficient to allow P. putida KT2440 to grow on 2-butanone. Not until all three genes were assembled in the recombinant P. putida was it able to use 2-butanone as carbon source. The Baeyer-Villiger monooxygenase activity of MekA was clearly demonstrated by incubating a mekB transposon insertion mutant of P. veronii with 2-butanone. Hereby, ethyl acetate was accumulated. To our knowledge, this is the first time that ethyl acetate by gas chromatographic analysis has been definitely demonstrated to be an intermediate of MEK degradation. The mekB-encoded protein was heterologously expressed in E. coli and purified by immobilized metal affinity chromatography. The protein exhibited high esterase activity towards short chain esters like ethyl acetate and 4-nitrophenyl acetate.

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Section: Discussionmentioning

confidence: 97%

Degradation of Alkyl Methyl Ketones by Pseudomonas veronii MEK700

et al. 2007

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“…Apart from that, residues indirectly involved in the interactions with the substrate may be important in the bglycosidase specificity (42,43). However, the identification of them is not simple due to b-glycosidases large number of residues.…”

Section: Discussionmentioning

confidence: 99%

“…The relevance of the residue that interacts with the basal platform of the subsite þ 1 was also demonstrated by the conversion of the Thermus thermophilus b-glycosidase (Ttbgly) into a transglycosidase using directed evolution (43). This conversion involved a better fit of the acceptor of the transglycosylation reaction in the subsite þ 1.…”

Section: Molecular Basis Of Aglycone Specificitymentioning

confidence: 99%

Molecular basis of substrate specificity in family 1 glycoside hydrolases

Marana

2006

IUBMB Life (International Union of Biochemistry and Molecular B

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Summaryb-glycosidases are active upon a large range of substrates. Besides this, subtle changes in the substrate structure may result in large modifications on the b-glycosidase activity. The characterization of the molecular basis of b-glycosidases substrate preference may contribute to the comprehension of the enzymatic specificity, a fundamental property of biological systems. b-glycosidases specificity for the monosaccharide of the substrate nonreducing end (glycone) is controlled by a hydrogen bond network involving at least 5 active site amino acid residues and 4 substrate hydroxyls. From these residues, a glutamate, which interacts with hydroxyls 4 and 6, seems to be a key element in the determination of the preference for fucosides, glucosides and galactosides. Apart from this, interactions with the hydroxyl 2 are essential to the b-glycosidase activity. The active site residues forming these interactions and the pattern of the hydrogen bond network are conserved among all b-glycosidases. The region of the b-glycosidase active site that interacts with the moiety (called aglycone) which is bound to the glycone is formed by several subsites (1 to 3). However, the majority of the non-covalent interactions with the aglycone is concentrated in the first one, which presents a variable spatial structure and amino acid composition. This structural variability is in accordance with the high diversity of aglycones recognized by b-glycosidases. Hydrophobic interactions and hydrogen bonds are formed with the aglycone, but the manner in which they control the b-glycosidase specificity still remains to be determined.

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“…Overexpression and purification of the Tt gly enzyme were conducted as previously described (Feng et al 2005). The -galactosidase AgaB was overexpressed in XL1 blue cells and purified according to the procedure described in a previous paper (Dion et al 2001).…”

Section: Glycosidase Expression and Purificationmentioning

confidence: 99%

“…For this purpose, glycoside hydrolases have been particularly investigated but their use is limited by the competition between hydrolysis and transglycosylation reactions which are both catalyzed by these enzymes. To overcome this limitation, several protein engineering strategies, based on site directed mutagenesis (Mackensie et al 1998) or molecular directed evolution (Feng et al 2005), have been proposed to reduce and even eliminate the hydrolytic activities of glycosidases while keeping the transglycosylation activities. Other alternatives suggested to prevent the undesirable hydrolysis reaction were reducing the water activity by using organic solvents (van Rantwijk et al 1999) or using frozen buffer (ChiffoleauGiraud et al 1997).…”

Section: Introductionmentioning

confidence: 99%