Altering Substrate Specificity of Bacillus sp. SAM1606 alpha -Glucosidase by Comparative Site-specific Mutagenesis*

(Received for publication, July 29, 1996, and in revised form, October 3, 1996)

Misa Inohara-Ochiai Dagger , Toru Nakayama §, Rieko Goto §, Masahiro Nakao Dagger , Takashi Ueda § and Yuji Shibano par

From the Dagger  Suntory Research Center, 1-1-1, Wakayamadai, Shimamoto-cho, Mishima-gun, Osaka 618, Japan, the § Department of Nutritional Physiology, Faculty of Nutrition, Kobe Gakuin University, 518 Arise, Ikawadani-cho, Nishi-ku, Kobe, 651-21 Japan, and the par  Biomolecular Engineering Research Institute, 6-2-3, Furuedai, Suita, Osaka 565, Japan

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES


ABSTRACT

The Bacillus sp. SAM1606 alpha -glucosidase with a broad substrate specificity is the only known alpha -glucosidase that can hydrolyze alpha ,alpha '-trehalose efficiently. The enzyme exhibits a very high sequence similarity to the oligo-1,6-glucosidases (O16G) of Bacillus thermoglucosidasius and Bacillus cereus which cannot act on trehalose. These three enzymes share 80% identical residues within the conserved regions (CR), which have been suggested to be located near or at the active site of the alpha -amylase family enzymes. To identify by site-specific mutagenesis the critical residues that determine the broad substrate specificity of the SAM1606 enzyme we compared the CR sequences of these three glucosidases and selected five targets to be mutagenized in SAM1606 alpha -glucosidase, Met76, Arg81, Ala116, Gly273, and Thr342. These residues have been specifically replaced by in vitro mutagenesis with Asn, Ser, Val, Pro, and Asn, respectively, as in the Bacillus O16G. The 12 mutant enzymes with single and multiple substitutions were expressed and characterized kinetically. The results showed that the 5-fold mutation virtually abolished the affinity of the enzyme for alpha ,alpha '-trehalose, whereas the specificity constant for the hydrolysis of isomaltose, a good substrate for both the SAM1606 enzyme and O16G, remained essentially unchanged upon the mutation. This loss in affinity for trehalose was critically governed by a Gly273 right-arrow Pro substitution, whose effect was specifically enhanced by the Thr342 right-arrow Asn substitution in the 5-fold and quadruple mutants. These results provide evidence for the differential roles of the amino acid residues in the CR in determining the substrate specificity of the alpha -glucosidase.


INTRODUCTION

It has been shown that alpha -amylases, alpha -glucosidases, glucoamylases, cyclodextrin glucanotransferases, and pullulanases share several short conserved sequences (conserved regions, CR1) (1-5) and have also been suggested to have a common (beta /alpha )8-barrel fold (6, 7). These enzymes are also proposed to share a common reaction mechanism (3, 8, 9). These characteristics suggest a strong evolutionary relationship in the origin of these enzymes, which have thus been categorized into a single protein family called the alpha -amylase family. X-ray crystallographic studies of several members of this family showed that the CR are located at or near the active site and contain putative catalytic carboxylates (5, 10-12). Recent structural elucidation of alpha -amylases and cyclodextrin glucanotransferase complexed with their substrates or inhibitors has shown that some amino acid residues in these regions indeed interact with the bound ligands (13-16). These observations indicate the significance of the CR sequences in maintaining catalytic activity and specificity of the enzyme.

alpha -Glucosidase (EC 3.2.1.20) catalyzes the hydrolysis of 1-O-alpha -D-glucopyranosides with a net retention of anomeric configuration. The substrate specificity of alpha -glucosidase differs greatly with the source of the enzyme (17). The majority of alpha -glucosidases preferentially hydrolyzes maltose, whereas another class of alpha -glucosidases, dextrin 6-alpha -glucanohydrolase (oligo-1,6-glucosidase, O16G; EC 3.2.1.10), acts exclusively on the alpha -1,6-glucosidic linkage of isomaltooligosaccharides (18). We have recently found that a strain of thermophilic Bacillus, SAM1606, produced a novel thermostable alpha -glucosidase with a broad substrate specificity and high transglucosylation activity (19). The enzyme can hydrolyze efficiently a variety of 1-O-alpha -D-glucopyranosides such as alpha ,alpha '-trehalose (trehalose), maltose, nigerose, isomaltose, sucrose, turanose, maltotriose, maltotetraose, and isomaltotriose. Indeed, it was the first such alpha -glucosidase that could hydrolyze trehalose efficiently. We cloned the SAM1606 alpha -glucosidase gene to determine its primary structure and expressed it in Escherichia coli (20). SAM1606 alpha -glucosidase exhibited sequence similarities to the enzymes of the alpha -amylase family and contained the CR (Fig. 1) as well as a suggested (beta /alpha )8-barrel fold. Thus, the enzyme was also assigned as a member of the alpha -amylase family. Unexpectedly, we found that the enzyme exhibits extremely high sequence similarities (62-65% identity along the entire polypeptide chain and 80% identity within the CR sequences) to the O16G of Bacillus cereus and Bacillus thermoglucosidasius (21-23). These O16G themselves are 72% (along the entire polypeptide chain) or 80% (along the CR sequences) identical to each other but, very interestingly, are distinct from SAM1606 alpha -glucosidase in substrate specificity; the O16G cannot hydrolyze trehalose, maltose, and sucrose (18, 24, 25). Thus, limited structural differences within the CR have been suggested to govern the significant differences in substrate specificity.


Fig. 1. Comparison of the amino acid sequences in the CR in Bacillus sp. SAM1606 alpha -glucosidase (SUCR.BACSP; Ref. 20), oligo-1,6-glucosidases of B. thermoglucosidasius (O16G.BACTR; Ref. 22), and B. cereus (O16G.BACCE; Ref. 21) shown in boldface letters. CR sequences of porcine pancreatic alpha -amylase (AMYP.PIG; Ref. 32), which lacks CR1 and CR2, are also aligned (see "Discussion"). Residues conserved in the three alpha -glucosidases are indicated by asterisks above the sequences. Arrows with numerals (in italics) above the sequences indicate the amino acid residues that are identical in the oligo-1,6-glucosidases but are different in SAM1606 alpha -glucosidase and are the targeted sites for mutagenesis in this study. Putative catalytic residues demonstrated by x-ray crystallographic studies of several alpha -amylase family enzymes are indicated below the sequences by a plus sign.
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In this study we have analyzed the broad substrate specificity of SAM1606 alpha -glucosidase by comparative site-specific mutagenesis. By comparing the CR sequences between the SAM1606 enzyme and the Bacillus O16G, we selected five targets to be mutagenized in the CR of SAM1606 alpha -glucosidase: Met76, Arg81, Ala116, Gly273, and Thr342. These residues have been specifically replaced by Asn, Ser, Val, Pro, and Asn, respectively, by in vitro mutagenesis, as are found in the O16G (Fig. 1). The mutant enzymes with their single and multiple substitutions were overexpressed and characterized kinetically. The results showed that the multiple mutations containing Gly273 right-arrow Pro and Thr342 right-arrow Asn caused an alteration in substrate specificity: affinity for trehalose has been specifically diminished upon the mutations. We describe here the mutational analyses of SAM1606 alpha -glucosidase to identify Gly273 right-arrow Pro as a critical substitution for differential specificity between the SAM1606 enzyme and O16G and find enhancement of its effect by Thr342 right-arrow Asn.


EXPERIMENTAL PROCEDURES

Chemicals

p-Nitrophenyl alpha -D-glucopyranoside, maltose, isomaltose, sucrose, and trehalose, all of analytical grade, were obtained from Nacalai Tesque, Kyoto, Japan. Maltose was freed from contaminant glucose by high performance liquid chromatography on an Asahipak NH2P50 column (1 × 25 cm) using a Shimadzu LC9A system in which 70% (v/v) CH3CN in H2O was isocratically developed at a flow rate of 2.0 ml/min by monitoring using thin layer chromatography (19). To find the exact concentration of isomaltose, which is supplied as a syrup containing water, isomaltose was hydrolyzed in 1 M HCl at 100 °C for 24 h. After neutralization with NaOH, the glucose formed was determined by the method of Pütter and Becker (26) using a kit (Boehringer Mannheim). For all other chemicals, the purest reagents available were used.

Bacterial Strains and Plasmids

Plasmid pGBSU2, a derivative of pGBSU1 (20), was used as a template in in vitro mutagenesis of the alpha -glucosidase gene. E. coli strain W3110 was used for expression of the wild type and all of the mutant alpha -glucosidases.

Site-directed Mutagenesis and Expression

A strategy for in vitro mutagenesis is depicted in Fig. 2A. Fragments I, II, III, and IV of the SAM1606 alpha -glucosidase gene were amplified by PCR using a template plasmid pGBSU2 (Fig. 2B), and the PCR primers (see also Table I) which were so designed that the restriction enzyme sites were newly created at boundaries of neighboring fragments without a change in the amino acid sequences. Fragments I, II, III, and IV were ligated with each other, and the resultant fragment was substituted for the BamHI-AatII fragment of the pGBSU2 to obtain pGBSU5 (Fig. 2C). Replacement of the fragment(s) in the pGBSU5 with the mutated fragment(s), whose preparations are described below, allowed us to obtain alpha -glucosidase genes having various combinations of mutations. The mutations Met76 right-arrow Asn, Arg81 right-arrow Ser, Ala116 right-arrow Val, and their double and triple mutations were introduced on the amplified fragment II essentially as described by Kramer and Frits (27) using the mutagenesis primers M1, M2, and M3. For the mutation Gly273 right-arrow Pro, fragments IIIa and IIIb were amplified from pGBSU2 using PCR primers F-IIIa/R-IIIa and F-IIIb/R-IIIb, respectively, which were so designed that the amplified fragments were to be ligated at a newly created SmaI site, giving rise to the substitution of Pro for Gly273. The mutation Thr342 right-arrow Asn was introduced by PCR, which was directly performed on the pGBSU2 with PCR primers M5 (instead of F-IV) and R-IV. Individual mutations were verified by DNA sequencing.


Fig. 2. Strategy for in vitro mutagenesis. Panel A, a black rectangle indicates a BamHI-HindIII fragment encoding the full-length SAM1606 alpha -glucosidase gene with white circles shown with numerals (in italics) indicating sites of amino acid substitutions (see Fig. 1). White rectangles with Roman numerals indicate amplified DNA fragments of the SAM1606 alpha -glucosidase gene by PCR using the PCR primers (arrows) shown above the fragments. Restriction enzyme sites (vertical lines), except for the terminal BamHI and HindIII sites, are those to be newly created by PCR. Horizontal lines (M1-M3) and an arrow (M5) shown below the fragments are the mutagenesis primers for amino acid substitutions. For further details, see "Results" and Table I. Panel B, a restriction enzyme map for plasmid pGBSU2, a template for the amplification of fragments, containing the full-length coding region for the wild type SAM1606 alpha -glucosidase gene (black arrow) in which the initiation codon was changed from TTG to ATG (see Ref. 20). icp indicates the 0.15-kilobase icp promoter region of the insecticidal crystal protein gene from B. thuringensis subsp. sotto, and a gray arrow indicates an ampicillin resistance (Ampr) gene. Numbers in parentheses indicate distances in kilobase pairs from the first nucleotide of the icp promoter region. It should be noted that for the construction of pGBSU5, a unique HindIII site of pGBSU2 was inactivated by digestion of the plasmid with HindIII and then blunted with T4 DNA polymerase followed by blunt end ligation with SalI adopter molecules. Panel C, a general restriction enzyme map for pGBSU5 and its derivatives, which were obtained by replacing the fragment(s) in the pGBSU5 with mutated one(s). Only the plasmids with the Gly273 right-arrow Pro substitution have an SmaI site, which is shown in a square brackets.
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Table I.

Synthetic oligonucleotides used in the mutagenesis of SAM1606 alpha -glucosidase


F-I CAGGATCCACCGCCTTGACG
R-I TTGAGGTAGTCAAGCTTCGAGAGG
F-II CATCCTCTCGAAGCTTGACTACCTC
R-II GCGAGGATCTAGACTCGATGAACC
F-IIIa ATCGAGTCTAGATCCTCGCGC
R-IIIa TGTCGTCACCCCGGGGGTCTCG
F-IIIb AGACCCCCGGGGTGACGACAAAGGG
R-IIIb TACAGGGAATTCCAGGCCTTGC
F-IV GGCCTGGAATTCCCTGTACTGG
R-IV GTTGTGGAGCTCGACGTCCC
M1 GAATGACGACAATGGCTATGAC
M2 CTATGACATCAGCGACTACTAC
M3 GGACCTGGTGGTCAACCATACCT
M5 CTGGAATTCCCTGTACTGGAACAACC

Mutant and wild type alpha -glucosidase genes were expressed in E. coli W3110 transformant cells under the control of the icp promoter of the insecticidal protein gene from B. thuringensis subsp. sotto as described (20, 28). E. coli transformant cells were grown to the stationary phase at 37 °C in 5 liters of L-broth containing 50 µg/ml ampicillin, and the cells were collected by centrifugation.

Enzyme Purification

The wild type and all of the mutant alpha -glucosidases were purified as described below. All steps were done at 4 °C unless otherwise stated. Sodium phosphate buffer (0.01 M, pH 7.0) was used as the standard buffer. Enzyme activity was routinely found by assay method I (see below). Cells (typically 20 g, wet weight) were ground with 40 g of aluminum oxide powder for 10 min in a mortar chilled on ice and suspended in 40 ml of standard buffer followed by centrifugation. Polyethyleneimine was added to the supernatant at a final concentration of 0.12% (w/v). After the mixture was left for 30 min, the precipitate was removed by centrifugation. The supernatant was then kept at 60 °C for 30 min. After the heat treatment, the precipitate was removed by centrifugation. To the supernatant solution, solid ammonium sulfate was added slowly to 20% saturation. After the mixture was allowed to stand for 1 h, the insoluble material was removed by centrifugation. Sodium ammonium sulfate was then added to 50% saturation. The precipitate, 20-50% saturated fraction, was dissolved in the standard buffer and dialyzed against the standard buffer. The insoluble material formed during the dialysis was removed by centrifugation. The enzyme solution was loaded on a DEAE-Sepharose CL-6B column (3.6 × 21 cm) equilibrated with the standard buffer. The enzyme was eluted with a linear gradient of NaCl (0-0.6 M) in the same buffer (400 ml each). Active fractions were analyzed for the subunit structure of the enzyme by native- and SDS-polyacrylamide gel electrophoresis (PAGE). It was found that at this step, a small fraction of the monomeric form of the enzyme could be separated from multimeric forms. Fractions containing >90% pure monomer were collected and concentrated with PM10 membrane in an Amicon 8200 ultrafiltration unit. The concentrate was put on a Sephacryl S200 HR column (2.6 × 67 cm) equilibrated with the standard buffer containing 0.1 M NaCl and eluted. The monomeric alpha -glucosidase fractions were combined, concentrated by ultrafiltration, dialyzed against the standard buffer, and used for kinetic analyses.

Enzyme Assay

Method I

The enzymatic hydrolysis of p-nitrophenyl alpha -D-glucopyranoside was monitored by the amount of p-nitrophenolate released at 55 °C. The standard assay mixture contained 1.0 µmol of p-nitrophenyl alpha -D-glucopyranoside, 10 µmol of sodium phosphate buffer, pH 7.2, and the enzyme in a final volume of 1.0 ml. The mixture without the enzyme was brought to 55 °C. The reaction was started by the addition of enzyme, and changes in absorbance at 405 nm were recorded with a spectrophotometer (Shimadzu UV-160; kinetic mode) equipped with a temperature-controlled cell positioner (CPS240A). The extinction coefficient for p-nitrophenolate under these conditions was 13,400 cm-1 M-1 (19).

Method II

For the kinetic analysis for hydrolysis of trehalose, maltose, sucrose, and isomaltose, the reaction mixture contained varying amounts of sugar, 1.0 µmol of sodium phosphate buffer, pH 7.2, and the enzyme in a final volume of 100 µl. The mixture without the enzyme was brought to 55 °C. The reaction was started by the addition of enzyme. After incubation at 55 °C for 10 min, the reaction was stopped by heating at 100 °C for 3 min. Glucose that formed in the reaction mixture was determined by the method of Pütter and Becker (26) with a kit (Boehringer Mannheim). The blank did not contain the enzyme. One unit of the enzyme is defined as the amount of enzyme which catalyzes the hydrolysis of 1 µmol of substrate/min at 55 °C. Km and Vmax values and their standard errors were estimated by fitting the initial velocity data to the Michaelis-Menten equation by nonlinear regression methods (29). The absorption coefficient of the purified SAM1606 alpha -glucosidase, A280[1%] = 25.5, which was calculated from the amino acid sequence (20), was used for unit calculations.

pH Activity Profiles

Enzymatic hydrolyses of trehalose, maltose, sucrose, and isomaltose were assayed by method II except that the reaction mixtures contained 5.0 µmol of substrate and 1.0 µmol of either sodium acetate, pH 2.0-6.0, or sodium phosphate, pH 6.0-8.0.

Analytical Methods

Native-PAGE and SDS-PAGE were done with a 10% gel by the procedures of Davis (30) and Laemmli (31), respectively. Proteins were stained with Coomassie Brilliant Blue R-250 and destained in a destaining solution (a 2:1:7 mixture of methanol, acetic acid, and water). For Western blotting, proteins in the SDS-PAGE gel were transferred to a nitrocellulose membrane, which was then blocked with 1% bovine serum albumin in phosphate-buffered saline, pH 7.2, at room temperature for 2 h. The blots were probed with a 1:400 dilution of the primary anti-SAM1606 alpha -glucosidase antiserum (rabbit) and the recommended dilution of secondary horseradish peroxidase coupled to goat anti-rabbit immunoglobulin G (Bio-Rad). The immune complexes were visualized by the peroxidase-catalyzed oxidation of 4-chloro-1-naphthol by hydrogen peroxide. The molecular weights of mutant and wild type alpha -glucosidases were estimated by gel permeation chromatography on TSK gel G3000SW-XL (0.7 × 25 cm) equilibrated with 0.01 M sodium phosphate buffer, pH 7.0, containing 0.15 M NaCl. The amino acid sequence from the amino terminus was determined by automated Edman degradation with a Shimadzu gas-phase sequencer (model PPSQ-10).


RESULTS

A series of mutant enzymes of SAM1606 alpha -glucosidase was constructed to probe amino acid residues as determinants for the specificity of the SAM1606 enzyme. The sites of mutagenesis and replacing amino acids were selected by comparing the CR sequences between the SAM1606 enzyme and O16G which exhibit striking sequence similarities but have distinct differences in their substrate specificity. We established a convenient system for construction and expression of mutant enzymes with all of the possible combinations of mutations (Fig. 2). Twelve of these mutants (Table II) were generated, all of which were expressed in E. coli cells and existed as both the monomeric and multimeric forms as the wild type enzyme. All of the mutant enzymes are stable during heat treatment at 60 °C and pH 7.0 for 30 min as is the wild type enzyme, and this permitted their efficient purifications. At the ion exchange chromatography step, a small fraction of the monomeric form could be separated from multimeric forms. The monomeric form thus separated was purified further to homogeneity by gel filtration chromatography on the criterion of native-PAGE. All of the purified mutant enzymes were eluted as a single peak corresponding to the expected native molecular weight (Mr 68,000), as confirmed by analytical gel permeation chromatography on TSK gel G3000SW, and were cross-reacted with polyclonal antibody raised against the wild type enzyme, as determined by Western blotting analysis. Amino-terminal amino acid sequence analyses up to 10 cycles of the wild type and all of the mutant enzymes confirmed the expected primary structure Ser-Thr-Ala-Leu-Thr-Gln-Thr-Ser-Thr-Asn (20).

Table II.

Nomenclature of mutant SAM1606 alpha -glucosidases

S, D, Q, and F denote multiplicity of mutations (single, double, quadruple, and 5-fold, respectively), and the numbers (in italics) denote the sites of mutation (see Fig. 1). The primes indicate that mutations were introduced at targeted sites other than that indicated.
Name Mutation

S1 Met76 right-arrow Asn
S2 Arg81 right-arrow Ser
S3 Ala116 right-arrow Val
S4 Gly273 right-arrow Pro
S5 Thr342 right-arrow Asn
D4/5 Gly273 right-arrow Pro/Thr342 right-arrow Asn
Q1' Arg81 right-arrow Ser/Ala116 right-arrow Val/Gly273 right-arrow Pro/Thr342 right-arrow Asn
Q2' Met76 right-arrow Asn/Ala116 right-arrow Val/Gly273 right-arrow Pro/Thr342 right-arrow Asn
Q3' Met76 right-arrow Asn/Arg81 right-arrow Ser/Gly273 right-arrow Pro/Thr342 right-arrow Asn
Q4' Met76 right-arrow Asn/Arg81 right-arrow Ser/Ala116 right-arrow Val/Thr342 right-arrow Asn
Q5' Met76 right-arrow Asn/Arg81 right-arrow Ser/Ala116 right-arrow Val/Gly273 right-arrow Pro
F Met76 right-arrow Asn/Arg81 right-arrow Ser/Ala116 right-arrow Val/Gly273 right-arrow Pro/Thr342 right-arrow Asn

The steady-state kinetic parameters for hydrolysis of four different substrates, trehalose, maltose, sucrose, and isomaltose, were determined for the wild type and mutant enzymes at pH 6.0 and are given in Table III. Among these substrates, trehalose is known to be a very poor substrate for most known alpha -glucosidases including the Bacillus O16G but has been shown to be hydrolyzed effectively by SAM1606 alpha -glucosidase. Maltose and sucrose were also substrates for which distinct differences in reactivity have been established between the SAM1606 enzyme and O16G, whereas isomaltose can serve as an excellent substrate for both enzymes.

Table III.

Kinetic parameters determined for wild type and mutant alpha -glucosidases

Assays were performed at pH 6.0 and 55 °C by assay method II as described under "Experimental Procedures."
Substrate and enzymea Km Vmax Vmax/Km

mM units/mg units/mg/mM
Trehalose
  Wild type 9.3  ± 2.4 16.5  ± 1.4 1.77
  S1 4.7  ± 1.0 16.5  ± 0.9 3.51
  S2 12.1  ± 1.1 17.9  ± 0.8 1.48
  S3 6.8  ± 1.3 15.4  ± 0.7 2.26
  S4 113  ± 24 12.0  ± 1.5 0.11
  S5 9.8  ± 1.1 20.6  ± 0.7 2.10
  D4/5 88.7  ± 11 4.2  ± 1.1 0.05
  Q1' 1103  ± 267 4.8  ± 0.9 0.004
  Q2' 1001  ± 338 6.5  ± 1.7 0.006
  Q3' 1210  ± 439 7.1  ± 2.2 0.006
  Q4' 4.9  ± 1.6 6.6  ± 0.3 1.35
  Q5' 117  ± 36 4.6  ± 1.3 0.04
  F 1183  ± 401 16.7  ± 4.6 0.014
Maltose
  Wild type 7.5  ± 2.6 14.7  ± 1.5 1.96
  S1 4.4  ± 1.5 18.8  ± 1.6 4.27
  S2 5.8  ± 1.6 10.5  ± 0.8 1.81
  S3 13.9  ± 2.2 29.1  ± 1.5 2.09
  S4 11.5  ± 4.4 5.7  ± 0.6 0.50
  S5 2.4  ± 0.6 18.9  ± 1.0 7.88
  Q4' 1.9  ± 0.3 14.1  ± 1.2 7.42
  F 36.2  ± 11 9.6  ± 1.3 0.26
Sucrose
  Wild type 6.9  ± 1.6 56.2  ± 4.3 8.14
  S1 7.2  ± 1.2 46.5  ± 2.1 6.46
  S2 7.2  ± 1.3 77.4  ± 2.7 10.8
  S3 8.5  ± 2.3 39.1  ± 2.8 4.60
  S4 9.1  ± 2.5 26.6  ± 2.2 2.92
  S5 6.8  ± 1.6 35.7  ± 2.3 5.25
  Q4' 16.4  ± 6.9 12.8  ± 1.8 0.78
  F 10.5  ± 3.4 11.9  ± 1.0 1.13
Isomaltose
  Wild type 3.5  ± 0.9 34.0  ± 2.3 9.71
  S1 4.0  ± 1.1 39.5  ± 2.8 9.88
  S2 3.7  ± 0.7 34.0  ± 1.5 9.19
  S3 1.7  ± 0.8 37.0  ± 3.4 21.8
  S4 5.8  ± 2.2 35.3  ± 4.2 6.09
  S5 3.8  ± 1.0 50.8  ± 3.2 13.4
  D4/5 1.4  ± 0.2 10.6  ± 3.3 7.57
  Q1' 9.0  ± 3.0 18.1  ± 2.2 2.01
  Q2' 16.0  ± 2.7 30.0  ± 2.9 1.88
  Q3' 13.9  ± 4.0 31.5  ± 3.3 2.27
  Q4' 9.9  ± 4.5 44.3  ± 7.3 4.47
  Q5' 16.1  ± 2.5 37.9  ± 1.1 2.35
  F 7.6  ± 1.1 37.4  ± 1.8 4.92

a  Abbreviations are as in Table II.

None of the single and multiple mutations caused a significant reduction in Vmax for all of the substrates tested; all mutant enzymes had Vmax values that were more than 20% of those of the wild type enzyme for all substrates. Some mutant enzymes exhibited even higher specific activities than that of the wild type enzyme. These are consistent with the fact that the mutagenic targets selected in this study did not contain the putative catalytic residues.

No significant variation in Km was detected with maltose, sucrose, and isomaltose upon each mutation. For trehalose, however, Gly273 right-arrow Pro as well as all multiple mutations containing the Gly273 right-arrow Pro mutation had distinct effects on Km from those obtained by the other mutations; only these mutations caused appreciable increases in the Km value for this substrate. In contrast, a quadruple mutant without the Gly273 right-arrow Pro substitution (i.e. Q4') showed a Km value for trehalose which was similar to that of the wild type enzyme. These results indicate that the increase in Km for trehalose is critically governed by the Gly273 right-arrow Pro substitution, which solely caused a 10-fold greater increase in the Km value than those of mutants without it, as shown by comparison of Km values for trehalose of S4 and the other single mutants. In addition, the results with mutants with four and five alterations also indicate that the effect of the Gly273 right-arrow Pro substitution was enhanced further by a Thr342 right-arrow Asn substitution in these mutants; the presence of Asn342 in these cases (i.e. Q1', Q2', Q3', and F) caused more than 10-fold additional increases in Km for trehalose than with the Gly273 right-arrow Pro mutants without Thr342 right-arrow Asn substitution (i.e. S4 and Q5', Table III). Interestingly, however, such an enhancement was not observed in the D4/5 mutant where the Thr342 right-arrow Asn substitution was only introduced into the single Gly273 right-arrow Pro mutant (S4). It should be emphasized that, judging from the Km values, Q1', Q2', Q3', and F cannot bind trehalose under the assay conditions that have been employed routinely with a relatively low substrate concentration (i.e. 5 mM; Ref. 19), albeit their Km values for isomaltose were almost unchanged (Table III).

To find the net changes in substrate preference of the enzyme upon mutations, we compared the relative specificity constants using isomaltose as the reference substrate (Fig. 3); isomaltose showed the least variation in the specificity constant upon all mutations (Table III), consistent with the fact that this sugar serves as a good substrate for both the SAM1606 enzyme and O16G. The largest changes in the substrate specificity were detected with mutant enzymes exhibiting exclusive diminutions in the relative specificity constant for trehalose.


Fig. 3. The specificity constants listed in Table III are expressed as the values with trehalose (panel A), maltose (panel B), and sucrose (panel C) relative to that observed with the reference substrate, isomaltose, for each enzyme.
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We also examined the apparent pH activity profiles for hydrolysis of these substrates with six representative mutants (S1, S2, S3, S4, S5, and F) to address the possibility that the observed change in the substrate specificity is due to a change in the pH dependence of the hydrolysis reaction upon mutations. Optimum pH values for hydrolysis of trehalose, maltose, and sucrose were at 5.5 for all six mutant enzymes and were unchanged from those of the wild type enzyme, although some variations in the optimum pH were observed with isomaltose. Optimum pH values were at 4.7 for the wild type enzyme, S1, S2, and S5, and at 3.5 for F; but S3 and S4 showed a broad optimum pH ranging from 4.5 to 6.0. Thus, the change in the specificity was not due to a specific shift in the pH optimum for trehalose hydrolysis.


DISCUSSION

The strategy we have taken in this study to probe amino acid residues responsible for the uniquely broad substrate specificity of the SAM1606 alpha -glucosidase can be called comparative site-specific mutagenesis; the sites and amino acids chosen for replacement were selected by comparing the CR sequences with those of reference enzymes that show high sequence similarities but have distinct and narrower substrate specificities. This strategy is based on the recent reports that the CR sequences are at or near active and substrate binding sites of the enzyme and are suggested to be important in determining the specificity of the enzyme (5, 10-16). The O16G of B. thermoglucosidasius and B. cereus were very good reference enzymes for the SAM1606 enzyme for this purpose because they are 80% identical to the SAM1606 enzyme in the CR but are very different in terms of substrate specificity from the SAM1606 enzyme (19, 20). Five nonconserved amino acids, Met76, Arg81, Ala116, Gly273, and Thr342, were identified and selected for mutagenesis and were replaced with Asn, Ser, Val, Pro, and Asn, respectively. Enzymes with all possible combinations of one through five mutations could be constructed easily and expressed in our established system.

In this study, examination of 12 of the possible mutant enzymes successfully led us to find that replacing Gly273 with Pro caused a significant and specific diminution of the affinity of an enzyme for trehalose without a significant decrease in Vmax value and thus permitted us to identify Gly273 as a critical determinant for differential reactivity to trehalose between the SAM1606 enzyme and O16G. The present studies also established the role of other amino acid residues in the CR in determining the specificity of the enzyme; the Thr342 right-arrow Asn substitution in the mutants with four and five alterations is important in enhancing the effect of the Gly273 right-arrow Pro substitution. Thus, the specificity of the alpha -glucosidase for trehalose arises from two distinct types of effects of amino acid residues. One of them determines critically the specificity, and the other enhances the effect of the Gly273 without any critical effect by itself. The latter effect by the Thr342 right-arrow Asn substitution was observed in the four- and five-substitution mutants, but not in the double mutant (D4/5), suggesting that the enhancement effect of the Thr342 right-arrow Asn substitution emerged in the enzymes with the CR sequences that are more similar to those of O16G than to that of the SAM1606 enzyme. Although the SAM1606 enzyme is the only known alpha -glucosidase that can efficiently act on trehalose (19, 20), these results suggest that this uniqueness is simply ascribed to the exclusive ability of the SAM1606 enzyme to bind this sugar efficiently. This implies that O16G and probably the other alpha -glucosidases of the same family lack the ability to bind trehalose because of their different CR sequences; however, they might be engineered genetically to hydrolyze trehalose by enabling them to bind trehalose through appropriate substitution of amino acid residues in their CR sequences, because these alpha -glucosidases are proposed to share a common reaction mechanism for cleaving the alpha -glucosidic linkages (3, 8, 9) and thus potentially allow hydrolysis of the alpha -1,1-linkage.

It should be pointed out that the effects of mutations on kinetic parameters varied with the substrates; contrary to the results obtained with trehalose, less variation in kinetic parameters was observed with maltose, sucrose, and isomaltose by mutations introduced in this study. Although distinct differences in reactivity have been established for maltose and sucrose between the SAM1606 and O16G enzymes, these differences could not be explained fully in terms of amino acid substitutions within the CR sequences. The current results indicate that replacement of the amino acid residues within the CR causes distinct effects on the reactivity of each substrate and suggest that critical amino acid residue(s) determining the reactivity to individual substrates may vary with the substrate. These conclusions are consistent with observations from x-ray crystallographic studies of several alpha -amylase family enzymes complexed with substrates and inhibitors (13-15). (i) Binding of a ligand to the enzyme is maintained through many polar and nonpolar protein-ligand interactions, including a hydrogen bonding network, which is in many cases engaged in interactions with the solvent water. (ii) Binding of a different ligand produces a different set of interactions. Thus, the five-substitution mutation may disrupt the interactions necessary for trehalose binding but may not essentially affect those interactions necessary for binding and subsequent catalytic steps in the hydrolysis of maltose, sucrose, and isomaltose, although it does somewhat perturb the pH dependence of isomaltose hydrolysis. Reactivity to sucrose and maltose of the SAM1606 enzyme may be governed by amino acid residue(s) other than the sites selected for mutagenesis in this study. Knowledge of the interactions between substrate and enzyme in the stereostructure of the SAM1606 alpha -glucosidase-substrate complex will be necessary to elucidate further the broad substrate specificity of this enzyme.

Gly273 and Thr342 are located near the putative catalytic residues of SAM1606 alpha -glucosidase, Glu271 and Asp345, and are positioned at less conserved sites in the CR of alpha -amylase family enzymes, implying their potential roles in defining the specificity. It is very interesting to find amino acid residues at positions in the CR corresponding to those of the Gly273 and Thr342 of the SAM1606 enzyme in the other enzymes of alpha -amylase family and their interactions with bound ligand in the reported stereostructures of the enzyme-inhibitor complexes. This is exemplified by the recent x-ray crystallographic studies of the porcine pancreatic alpha -amylase complexed with acarbose, a pseudosaccharidal inhibitor (13), and that with Temdamistat, a proteineous inhibitor (14). In this alpha -amylase, Ile235 and Asp297, respectively, correspond to the Gly273 and Thr342 of the SAM1606 enzyme (Fig. 1) and are located near the bound inhibitors. Particularly, Ile235 in the porcine pancreatic alpha -amylase appears to be in a close, though indirect, contact with the bound inhibitors. These observations corroborate the importance of Gly273 in substrate binding and the remarkable effect of its replacement with Pro.


FOOTNOTES

*   This work was supported in part by a grant for the development of highly functional materials by structural modification of carbohydrates (Project of Glycotechnology) from the Ministry of Agriculture, Forestry, and Fishery, Japan. The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
   To whom correspondence should be addressed. Tel.: 81-78-974-1551 (ext. 3254); Fax: 81-78-974-5689.
1    The abbreviations used are: CR, conserved region(s); O16G, oligo-1,6-glucosidase(s); trehalose, alpha ,alpha '-trehalose; PCR, polymerase chain reaction; PAGE, polyacrylamide gel electrophoresis. For the nomenclature of mutant enzymes, see Table II.

REFERENCES

  1. Nakajima, R., Imanaka, T., and Aiba, S. (1985) J. Bacteriol. 163, 401-406 [Medline] [Order article via Infotrieve]
  2. Svensson, B. (1988) FEBS Lett. 230, 72-76 [CrossRef][Medline] [Order article via Infotrieve]
  3. Takata, H., Kuriki, T., Okada, S., Takesada, Y., Iizuka, M., Minamiura, N., and Imanaka, T. (1992) J. Biol. Chem. 267, 18447-18452 [Abstract/Free Full Text]
  4. Toda, H., Kondo, K., and Narita, K. (1982) Proc. Jpn. Acad. 58, 208-212
  5. Matsuura, Y., Kusunoki, M., Harada, W., and Kakudo, M. (1984) J. Biochem. (Tokyo) 95, 697-702 [Abstract]
  6. MacGregor, E. A., and Svensson, B. (1989) Biochem. J. 259, 145-152 [Medline] [Order article via Infotrieve]
  7. Jesperson, H. M., MacGregor, E. A., Sierks, M. R., and Svensson, B. (1991) Biochem. J. 280, 51-55 [Medline] [Order article via Infotrieve]
  8. Hehre, E. J., Genghof, D. S., Strenlicht, H., and Brewer, C. F. (1977) Biochemistry 16, 1780-1787 [Medline] [Order article via Infotrieve]
  9. Kitahata, S., Brewer, C. F., Genghof, D. S., Sawai, T., and Hehre, E. J. (1981) J. Biol. Chem. 256, 6017-6026 [Abstract/Free Full Text]
  10. Qian, M., Haser, R., and Payan, F. (1993) J. Mol. Biol. 231, 785-799 [CrossRef][Medline] [Order article via Infotrieve]
  11. Brayer, G. D., Luo, Y., and Withers, S. G. (1995) Protein Sci. 4, 1730-1742 [Abstract/Free Full Text]
  12. Machius, M., Wiegand, G., and Huber, R. (1995) J. Mol. Biol. 246, 545-559 [CrossRef][Medline] [Order article via Infotrieve]
  13. Qian, M., Haser, R., Buisson, G., Duee, E., and Payan, F. (1994) Biochemistry 33, 6284-6294 [Medline] [Order article via Infotrieve]
  14. Wiegand, G., Epp, O., and Huber, R. (1995) J. Mol. Biol. 247, 99-110 [CrossRef][Medline] [Order article via Infotrieve]
  15. Knegtel, R. M. A., Strokopytov, B., Penninga, D., Faber, O. G., Rozeboom, H. J., Kalk, K. H., Dijkhuizen, L., and Dijkstra, B. W. (1995) J. Biol. Chem. 270, 29256-29264 [Abstract/Free Full Text]
  16. Casset, F., Imberty, A., Haser, R., Payan, F., and Perez, S. (1995) Eur. J. Biochem. 232, 284-293 [Abstract]
  17. Kelly, C. T., and Fogarty, W. M. (1983) Process Biochem. 18, 6-12
  18. Suzuki, Y., Aoki, R., and Hayashi, H. (1982) Biochim. Biophys. Acta 704, 476-483
  19. Nakao, M., Nakayama, T., Harada, M., Kakudo, A., Ikemoto, H., Kobayashi, S., and Shibano, Y. (1994) Appl. Microbiol. Biotechnol. 41, 337-343 [CrossRef][Medline] [Order article via Infotrieve]
  20. Nakao, M., Nakayama, T., Kakudo, A., Inohara, M., Harada, M., Omura, F., and Shibano, Y. (1994) Eur. J. Biochem. 220, 293-300 [Abstract]
  21. Watanabe, K., Kitamura, K., Iha, H., and Suzuki, Y. (1990) Eur. J. Biochem. 192, 609-620 [Abstract]
  22. Watanabe, K., Chishiro, K., Kitamura, K., and Suzuki, Y. (1991) J. Biol. Chem. 266, 24287-24294 [Abstract/Free Full Text]
  23. Watanabe, K., Masuda, T., Ohashi, H., Mihara, H., and Suzuki, Y. (1994) Eur. J. Biochem. 226, 277-283 [Abstract]
  24. Suzuki, Y., Yuki, T., Kishigami, T., and Abe, S. (1976) Biochim. Biophys. Acta 445, 386-397 [Medline] [Order article via Infotrieve]
  25. Suzuki, Y., Ueda, Y., Nakamura, N., and Abe, S. (1979) Biochim. Biophys. Acta 566, 62-66 [Medline] [Order article via Infotrieve]
  26. Pütter, J., and Becker, R. (1983) in Methods in Enzymatic Analysis (Bergmeyer, H. U., ed), p. 286, Verlag Chemie, Weinheim
  27. Kramer, W., and Frits, H. (1987) Methods Enzymol. 154, 350-359 [Medline] [Order article via Infotrieve]
  28. Shibano, Y., Yamagata, A., Nakamura, N., Iizuka, T., Sugisaki, H., and Takanami, M. (1985) Gene (Amst.) 34, 243-251 [Medline] [Order article via Infotrieve]
  29. Leatherbarrow, R. J. (1990) Trends Biochem. Sci. 15, 455-458 [CrossRef][Medline] [Order article via Infotrieve]
  30. Davis, B. J. (1964) Ann. N. Y. Acad. Sci. 121, 404-427 [Medline] [Order article via Infotrieve]
  31. Laemmli, U. K. (1970) Nature 227, 680-685 [Medline] [Order article via Infotrieve]
  32. Pasero, L., Mazzei-Pierron, Y., Abadie, B., Chicheportiche, Y., and Marchis-Mouren, G. (1986) Biochim. Biophys. Acta 869, 147-157 [Medline] [Order article via Infotrieve]

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