The Structure of an Archaeal α-Glucosaminidase Provides Insight into Glycoside Hydrolase Evolution

Mine, Shouhei; Watanabe, Masahiro; Kamachi, Saori; Abe, Yoshito; Ueda, Tadashi

doi:10.1074/jbc.m116.766535

Cited by 8 publications

(9 citation statements)

References 46 publications

(37 reference statements)

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“…The dimer displayed a higher activity of about two activity units (compared to the monomer) on the tested substrates, except for pachyman and curdlan. The active monomer of the Exg-D enzyme was found to be novel, as several studies have generally shown that dimeric oligomers of the GH enzymes are active, while their monomers are not active or display very low activity [13,[15][16][17]. The specific activity results were supported by biochemical characterisation and kinetic studies, which showed that the dimeric and monomeric species of Exg-D displayed the same pH and temperature optima.…”

Section: Discussionmentioning

confidence: 81%

A Novel Dimeric Exoglucanase (GH5_38): Biochemical and Structural Characterisation towards its Application in Alkyl Cellobioside Synthesis

et al. 2020

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An exoglucanase (Exg-D) from the glycoside hydrolase family 5 subfamily 38 (GH5_38) was heterologously expressed and structurally and biochemically characterised at a molecular level for its application in alkyl glycoside synthesis. The purified Exg-D existed in both dimeric and monomeric forms in solution, which showed highest activity on mixed-linked β-glucan (88.0 and 86.7 U/mg protein, respectively) and lichenin (24.5 and 23.7 U/mg protein, respectively). They displayed a broad optimum pH range from 5.5 to 7 and a temperature optimum from 40 to 60 • C. Kinetic studies demonstrated that Exg-D had a higher affinity towards β-glucan, with a K m of 7.9 mg/mL and a k cat of 117.2 s −1 , compared to lichenin which had a K m of 21.5 mg/mL and a k cat of 70.0 s −1 . The circular dichroism profile of Exg-D showed that its secondary structure consisted of 11% α-helices, 36% β-strands and 53% coils. Exg-D performed transglycosylation using p-nitrophenyl cellobioside as a glycosyl donor and several primary alcohols as acceptors to produce methyl-, ethyl-and propyl-cellobiosides. These products were identified and quantified via thin-layer chromatography (TLC) and liquid chromatography-mass spectrometry (LC-MS). We concluded that Exg-D is a novel and promising oligomeric glycoside hydrolase for the one-step synthesis of alkyl glycosides with more than one monosaccharide unit.

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Section: Discussionmentioning

confidence: 81%

A Novel Dimeric Exoglucanase (GH5_38): Biochemical and Structural Characterisation towards its Application in Alkyl Cellobioside Synthesis

et al. 2020

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“…From the structural comparison, Glu179 and Glu347 of GlmA Tk are sterically identical to the acid/base Glu188 and the nucleophile Glu268 of Hs-β-gal, respectively (Figure 4A, B, C). GlmA Tk mutations, E179Q and E347Q, resulted in dramatic activity loss [15], supporting the notion that these residues are involved in protein catalysis. Furthermore, these Glu residues are located in the β4 and β7 strands of the TIM-barrel domain and are separated by 4.8 Å [15].…”

Section: Glma Active Site and Catalytic Mechanismmentioning

confidence: 75%

“…GlmA Tk mutations, E179Q and E347Q, resulted in dramatic activity loss [15], supporting the notion that these residues are involved in protein catalysis. Furthermore, these Glu residues are located in the β4 and β7 strands of the TIM-barrel domain and are separated by 4.8 Å [15]. All proteins in the GH35 family belong to a GH-A clan that comprises enzymes with two conserved catalytic Glu residues in the C-terminals of β4 and β7 [17].…”

Section: Glma Active Site and Catalytic Mechanismmentioning

confidence: 75%

“…The structure of GlmA Ph was deduced using the single-wavelength anomalous dispersion of selenomethionine atoms and refined at 2.60-Å resolution (PDB 5GSL) [15]. The structure of GlmA Pf and GlcN-bound GlmA Tk was determined at 1.75-Å resolution (PDB 6JOW, unpublished) and 1.27-Å resolution (PDB 5GSM) [15], respectively, using molecular replacement of the structure of the GlmA Ph monomer as the search model. The structures of GlmA Ph and GlmA Pf showed little variation to that of GlmA Tk , as reflected in the RMSD values of 0.90 Å for 767 Cα atoms and 0.74 Å for 751 Cα atoms, respectively (Figure 1A).…”

Section: Structure and Thermostability Of Glmamentioning

confidence: 99%

“…To address this critical question, we determined the crystal structure of GlmA Tk (encoded by the TK1754 gene) from Thermococcus kodakaraensis KOD1 [15]. The crystal structures of two proteins, which are highly homologous to GlmA Tk , GlmA Ph (encoded by the PH0511 gene) [16] and GlmA Pf (encoded by the PF0363 gene) [14], from the closely related hyperthermophiles Pyrococcus species Pyrococcus horikoshii and Pyrococcus furiosus , respectively, were also determined.…”

Section: Introductionmentioning

confidence: 99%

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Structural Insights into the Molecular Evolution of the Archaeal Exo-β-d-Glucosaminidase

Mine

Watanabe²

2019

IJMS

Self Cite

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The archaeal exo-β-d-glucosaminidase (GlmA), a thermostable enzyme belonging to the glycosidase hydrolase (GH) 35 family, hydrolyzes chitosan oligosaccharides into monomer glucosamines. GlmA is a novel enzyme in terms of its primary structure, as it is homologous to both GH35 and GH42 β-galactosidases. The catalytic mechanism of GlmA is not known. Here, we summarize the recent reports on the crystallographic analysis of GlmA. GlmA is a homodimer, with each subunit comprising three distinct domains: a catalytic TIM-barrel domain, an α/β domain, and a β1 domain. Surprisingly, the structure of GlmA presents features common to GH35 and GH42 β-galactosidases, with the domain organization resembling that of GH42 β-galactosidases and the active-site architecture resembling that of GH35 β-galactosidases. Additionally, the GlmA structure also provides critical information about its catalytic mechanism, in particular, on how the enzyme can recognize glucosamine. Finally, we postulate an evolutionary pathway based on the structure of an ancestor GlmA to extant GH35 and GH42 β-galactosidases.

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Microbial β‐Galactosidases of industrial importance: Computational studies on the effects of point mutations on the lactose hydrolysis reaction

Andrade

Timmers

Renard

et al. 2020

Biotechnology Progress

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Hydrolysis efficiency of β‐galactosidases is affected due to a strong inhibition by galactose, hampering the complete lactose hydrolysis. One alternative to reduce this inhibition is to perform mutations in the enzyme's active site. The aim of this study was to evaluate the effect of point mutations on the active site of different microbial β‐galactosidases, using computational techniques. The enzymes of Aspergillus niger (AnβGal), Aspergillus oryzae (AoβGal), Bacillus circulans (BcβGal), Bifidobacterium bifidum (BbβGal), and Kluyveromyces lactis (KlβGal) were used. The mutations were carried out in all residues that were up to 4.5 Å from the galactose/lactose molecules and binding energy was computed. The mutants Tyr96Ala (AnβGal), Asn140Ala and Asn199Ala (AoβGal), Arg111Ala and Glu355Ala (BcβGal), Arg122Ala and Phe358Ala (BbβGal), Tyr523Ala, Phe620Ala, and Trp582Ala (KlβGal) had the best results, with higher effect on galactose binding energy and lower effect on lactose affinity. To maximize enzyme reactions by reducing galactose affinity, double mutations were proposed for BcβGal, BbβGal, and KlβGal. The double mutations in BcβGal and BbβGal caused the highest reduction in galactose affinity, while no satisfactory results were observed to KlβGal. Using computational tools, mutants that reduced galactose affinity without significantly affecting lactose binding were proposed. The mutations proposed can be used to reduce the negative feedback process, improving the catalytic characteristics of β‐galactosidases and rendering them promising for industrial applications.

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The Structure of an Archaeal α-Glucosaminidase Provides Insight into Glycoside Hydrolase Evolution

Cited by 8 publications

References 46 publications

A Novel Dimeric Exoglucanase (GH5_38): Biochemical and Structural Characterisation towards its Application in Alkyl Cellobioside Synthesis

A Novel Dimeric Exoglucanase (GH5_38): Biochemical and Structural Characterisation towards its Application in Alkyl Cellobioside Synthesis

Structural Insights into the Molecular Evolution of the Archaeal Exo-β-d-Glucosaminidase

Microbial β‐Galactosidases of industrial importance: Computational studies on the effects of point mutations on the lactose hydrolysis reaction

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