A Bifunctionalized Fluorogenic Tetrasaccharide as a Substrate to Study Cellulases*

(Received for publication, April 8, 1996, and in revised form, October 24, 1996)

Sylvie Armand Dagger , Sophie Drouillard Dagger , Martin Schülein , Bernard Henrissat Dagger par and Hugues Driguez Dagger par

From the Dagger  Centre de Recherches sur les Macromolécules Végétales,  CNRS, F-38041 Grenoble cedex 9, France and  Novo-Nordisk a/s, Novo Allé, DK-2880 Bagsvaerd, Denmark

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
FOOTNOTES
Acknowledgments
REFERENCES


ABSTRACT

Cellulases are usually classified as endoglucanases and cellobiohydrolases, but the heterogeneity of cellulose, in terms of particle size and crystallinity, has always represented a problem for the biochemical characterization of the enzymes. The synthesis of a bifunctionalized tetrasaccharide substrate suitable for measuring cellulase activity by resonance energy transfer is described. The substrate, which carries a 5-(2-aminoethylamino)-1-naphthalenesulfonate group on the non-reducing end and an indolethyl group on the reducing end, was prepared from beta -lactosyl fluoride and indolethyl beta -cellobioside by a chemoenzymatic approach using the transglycosylating activity of endoglucanase I of Humicola insolens as the key step. The bifunctionalized substrate has been used for the determination of the catalytic constants of H. insolens endoglucanase I and cellobiohydrolases I and II; this substrate could be of general use to measure the kinetic constants of cellulases able to act on oligomers of degree of polymerization <5. The data also provide evidence that cellobiohydrolases I and II are able to degrade an oligosaccharide substrate carrying non-carbohydrate substituents at both ends.


INTRODUCTION

Cellulose is a fibrous, insoluble, and crystalline polysaccharide made of beta (1,4)-linked D-glucopyranosyl residues and constitutes the major structural component of plant cell walls and the most abundant biopolymer on Earth with approximately 109 tons biosynthesized and degraded each year (1). Cellulolytic organisms (mostly bacteria and fungi) produce a consortium of cellulases usually classified as cellobiohydrolases (CBH1; 1,4-beta -D-glucan cellobiohydrolase, EC 3.2.1.91) and endoglucanases (EG; 1,4-beta -D-glucan glucanohydrolase, EC 3.2.1.4) which degrade cellulose in a synergistic manner (2, 3). Cellulases are currently grouped in different families, according to a classification of glycosyl hydrolases based on amino acid sequence similarities (4, 5). Quite unexpectedly, this classification does not coincide with the above biochemical division since a given family can contain CBH as well as EG.

Because of the abundance, the properties, and the many uses of cellulose, cellulolytic enzymes have considerable ecological as well as industrial importance. However, the heterogeneity of native cellulose, in terms of particle size and crystallinity, has always represented a problem for the biochemical characterization of cellulases. Small soluble substrates containing a chromophoric group at the reducing end have proved to be very useful for the specificity mapping of various cellulases (6). However, the use of these substrates for kinetic studies is limited since the enzymatic cleavage is monitored directly only when it occurs between the sugar and the aglycon.

The aim of this work is the synthesis of a bifunctionalized tetrasaccharide substrate for cellulases to provide a sensitive assay to determine the kinetic parameters of different cellulases using micromolar concentrations of substrate. This substrate contains two fluorogenic groups, respectively, at the reducing and non-reducing end of the molecule. The principle of the assay is based on the fact that the chromophore donor and the fluorophore acceptor are in sufficient proximity in the substrate to allow a resonance energy transfer between the two fluorogenic groups. After hydrolysis of any glycosidic bond in the substrate, the two fluorogenic groups are separated, and the resonance energy transfer is no longer possible. The decrease in resonance energy transfer therefore provides a convenient way to monitor the enzymatic reaction. This strategy has been used previously for the assay of proteolytic enzymes (7, 8) and of alpha -amylases (9). To overcome the problems related to a chemical synthesis of a complex tetrasaccharide containing four beta -1,4-linkages, a chemoenzymatic approach has been developed for the preparation of the bifunctionalized substrate. A similar strategy was used recently for obtaining a disubstituted maltopentaoside for the assay of alpha -amylases (9). The enzyme used for the enzymatic condensation is the recombinant endoglucanase I from the fungus Humicola insolens, which has previously been shown to exhibit a high transglycosylating activity (10).

The preparation of the tetrasaccharide indolethyl 6-N-6-(5-(2-aminoethylamino)-1-naphthalenesulfonate)-6-deoxy-beta -D-galactopyranosyl-4-O-(beta -D-glucopyranosyl)-4-O-(beta -D-glucopyranosyl)-4-O-beta -D-glucopyranoside IX, is reported (Fig. 1). This substrate, which provides a sensitive assay for cellulolytic enzymes, proved useful for the determination of the kinetic parameters of several recombinant cellulases from H. insolens.


Fig. 1. Synthesis of the bifunctionalized tetrasaccharide IX.
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EXPERIMENTAL PROCEDURES

Enzymes

The H. insolens cellulases were all cloned and expressed in Aspergillus oryzae (11-13). Endoglucanase V (EGV) and cellobiohydrolase I (CBHI) were purified using Avicel affinity chromatography as described (14). EGV and CBHI gave single bands in SDS-polyacrylamide gel electrophoresis at 43 and 70 kDa, respectively. Their respective molar absorption coefficients were of 61,300 and 89,700 cm-1 M-1. Endoglucanase I (EGI) and cellobiohydrolase II core (CBHII core) were purified using ion exchange chromatography. EGI was applied to cation exchange chromatography using Mono S (Pharmacia Biotech Inc.) and 50 mM sodium acetate buffer, pH 5.0. Pure EGI was eluted using a pH gradient from 50 mM sodium acetate buffer, pH 5.0, to 100 mM potassium phosphate, pH 7.0. EGI showed a single band in SDS-polyacrylamide gel electrophoresis at 50 kDa and had a molar absorption coefficient of 66,300 cm-1 M-1. CBHII core was purified by anion exchange chromatography (DEAE-Sepharose) and 20 mM triethanolamine buffer, pH 8.0. CBHII core was eluted using a 0-1 M sodium chloride gradient. The enzyme was purified further by size chromatography on S-300 Sephacryl (Pharmacia) using 0.1 M sodium acetate buffer, pH 6.1. Purified CBHII core gave a single band in SDS-polyacrylamide gel electrophoresis at 42 kDa and had a molar absorption coefficient of 77,260 cm-1 M-1.

Methods

All of the new compounds displayed elemental analysis and NMR and mass spectra in accordance to their structure. NMR spectra were recorded on a Bruker AC 300 spectrometer at 300 MHz for 1H and 75 MHz for 13C and on a Varian Unity Plus at 500 MHz for 1H. The mass spectra were recorded on a Nermag R-1010C spectrometer. Optical rotations were measured at 20 °C on a Perkin-Elmer 241 polarimeter. The enzymatic condensation reaction was analyzed by HPLC using an analytical NH2 column (µBondapak, Waters) equipped with a refractometric detector and eluted with acetonitrile/water, 77.5:22.5.

Preparation of beta -Lactosyl Fluoride (II)

Hepta-O-acetyllactosyl bromide I was prepared in a conventional fashion (15). beta -Lactosyl fluoride II was synthesized by reacting hepta-O-acetyllactosyl bromide I (14 g; 0.02 mol) with silver fluoride (5.2 g; 0.041 mol) in anhydrous acetonitrile (156 ml) for 4 h at 22 °C. The hepta-O-acetyllactosyl fluoride product was purified by flash chromatography on silica gel (ethyl acetate/light petroleum, 1:1.5 v/v), crystallized from ether (yield 63%), and characterized; mp 78-80 °C; alpha D25 = +9° (c = 1.0 in CHCl3); 1H NMR (300 MHz, CDCl3) delta  = 5.32 (dd, J(H-11, F) = 53 Hz, J(H-11, H-21) = 5 Hz, H-11); 13C NMR (75.4 MHz, CDCl3) delta  = 170.16-169.00 (7 × CO), 105.55 (d, J(C-11, F) = 218 Hz, C-11), 101.12 (C-12), 20.88-20.34 (7 × CH3). After deacetylation in the presence of 0.5 M sodium methoxide in methanol for 3 h at 0 °C, beta -lactosyl fluoride II was neutralized with a (H+) resin, recovered, and used immediately without further characterization.

Preparation of Indolethyl beta -Cellobioside (V)

Hepta-O-acetylcellobiosyl bromide III was prepared in a conventional fashion (15). Glycosylation of bromide III (2.9 g, 4.15 mmol) with 3-(2-hydroxyethyl)indole (333 mg, 2.07 mmol) was achieved in anhydrous toluene (40 ml) and nitromethane (40 ml) in the presence of HgCN2 (950 mg) and HgBr2 (67 mg), for 18 h at 22 °C. The expected disaccharide IV was purified by flash chromatography on silica gel (ethyl acetate/light petroleum, 1:1 v/v), isolated with a yield of 40% and characterized; mp 96-98 °C; alpha D25 = -20° (c = 0.5 in CHCl3); FAB-MS (3-nitrobenzyl alcohol + KCl): m/z: 779 [M+]; 13C NMR (75.4 MHz, CDCl3) delta  = 171.01-168.95 (7 × CO), 136.06, 127.36, 122.24, 121.77, 119.15, 118.52, 112.12, 111.04 (aromatic C in indole), 100.64, 100.54 (C-11, C-12), 61.88, 61.47 (C-61, C-62), 20.91-20.39 (7 × CH3). After conventional deacetylation of IV in the presence of 0.5 M sodium methoxide in methanol, indolethyl cellobioside V was obtained and characterized; alpha D25 = -11° (c = 0.5 in H2O); FAB-MS (glycerol): m/z: 485 [M+]; 1H NMR (300 MHz, D2O) delta  = 7.54 (d, J = 8 Hz, 1H in indole), 7.36 (d, J = 8 Hz, 1H in indole), 7.11 (m, 1H in indole), 7.10 (s, 1H in indole), 7.02 (m, 1H in indole), 4.33, 4.27 (2d, J = 8 Hz, 2H, H-11, H-12), 4.05-2.90 (16H); 13C NMR (75.4 MHz, D2O) delta  = 137.61, 128.37, 125.00, 123.31, 120.61, 120.08, 113.31, 112.58 (aromatic C in indole), 104.01, 103.56 (C-11, C-12), 62.05, 61.51 (C-61, C-62).

Preparation of Indolethyl 4-O-beta -D-Galactopyranosyl-4-O-beta -D-glucopyranosyl-4-O-beta -D-glucopyranosyl-4-O-beta -D-glucopyranoside (VI)

H. insolens endoglucanase I (134 µl, 4 mg/ml) in maleate buffer (0.05 M, pH 7.0) was added to a solution of beta -lactosyl fluoride II (413 mg, 1.2 mmol) in 4 ml of maleate buffer (0.05 M, pH 7.0) and acetonitrile (12 ml). After stirring 1 min at 40 °C, indolethyl cellobioside V (194 mg, 400 µmol) in the same buffer (4 ml) was added. The solution was kept at 40 °C, and fresh enzyme (134 µl each time) was added after 10 and 30 min. The reaction was monitored by HPLC. After 55 min, almost all indolethyl cellobioside V was consumed, and about 70% of the tetrasaccharide VII was formed. The solution was brought to pH 9.0 by the addition of NH4OH, and the mixture was heated for 10 min at 100 °C to deactivate the enzyme. After a flash chromatography on a reversed phase column packed with LiChroprep RP-18, 5-20 µm (Merck), eluted with a gradient from water to water/methanol (70:30 v/v) to eliminate the buffer and the lactose formed, the mixture was acetylated (24 h) at ambient temperature with acetic anhydride (6 ml) and pyridine (6 ml) in the presence of a catalytic amount of N,N-dimethylaminopyridine. After chromatography on silica gel using ethyl acetate/dichloromethane as eluent (1:3, then 1:2, 1:1, and finally 2:1), the per-O-acetyltetrasaccharide VI (60% yield) was crystallized from ethanol and characterized; mp 134-137 °C; alpha D25 = -18° (c = 1 in CHCl3); FAB-MS (3-nitrobenzyl alcohol): m/z: 1355 [M+]; 13C NMR (75.4 MHz, CDCl3) delta  = 170.36-169.12 (13 × CO), 136.12, 127.44, 122.24, 121.93, 119.32, 118.64, 112.39, 111.06 (aromatic C in indole), 101.07, 100.61, 100.43, 100.40 (C-11, C-12, C-13, C-14), 20.83-20.44 (13 × CH3). Conventional deacetylation of VI afforded pure tetrasaccharide VII that crystallized from methanol; mp > 280 °C; alpha D25 = -2° (c = 1 in H2O); FAB-MS (glycerol): m/z: 809 [M+]; 1H NMR (500 MHz, D2O) delta  = 7.60 (d, J = 8 Hz, 1H in indole), 7.38 (d, J = 8 Hz, 1H in indole), 7.16 (s, 1H in indole), 7.13 (m, 1H in indole), 7.04 (m, 1H in indole), 4.40, 4.39, 4.38 (3d, J = 7.5 Hz, H-11, H-12, H-13), 4.27 (d, J = 7.5 Hz, H-14), 4.10-2.95 (28H); 13C NMR (75.4 MHz, D2O) delta  = 137.60, 128.28, 125.08, 123.35, 120.60, 120.07, 113.30, 112.60 (aromatic C in indole), 104.39-103.56 (C-11, C-12, C-13, C-14), 80.03, 79.77, 79.63 (C-41, C-42, C-43), 62.48 (C-64), 61.47-61.34 (C-61, C-62, C-63).

Preparation of Bifunctionalized Tetrasaccharide (IX)

Incubation of tetrasaccharide VII (52 mg, 64 µmol) with galactose oxidase from Dactylium dendroides (Fluka, 36 units) and catalase from bovine liver (Sigma, 360 units) at 25 °C in 1 mM CuSO4 for 15 h under ~2 bar air pressure gave compound VIII in quantitative yield. Reductive amination of VIII (22.6 mg, 28 µmol) in the presence of EDANS (31.4 mg, 109 µmol) and NaBH3CN (12.5 mg, 199 µmol) in methanol (6 ml) at 22 °C for 24 h gave tetrasaccharide IX. Purification by chromatography on a reversed phase column packed with LiChroprep RP-18, 5-20 µm (Merck) eluted first with water and then with a gradient of water and methanol afforded the bifunctionalized tetrasaccharide IX (60% yield); alpha D25 = ~0° (c = 0.23 in dimethyl sulfoxide); FAB-MS (glycerol): m/z: 1,079 [M+]; 1H NMR (500 MHz, D2O) delta  = 8.10 (d, J = 9 Hz, 1H in EDANS), 8.01 (d, J = 7.5 Hz, 1H in EDANS), 7.96 (d, J = 9 Hz, 1H in EDANS), 7.60 (d, J = 8 Hz, 1H in indole), 7.46 (m, 1H in EDANS), 7.43 (m, 1H in EDANS), 7.38 (d, J = 8 Hz, 1H in indole), 7.16 (s, 1H in indole), 7.13 (m, 1H in indole), 7.04 (m, 1H in indole), 6.75 (d, J = 7.5 Hz, 1H in EDANS), 4.40, 4.38, 4.32, 4.30 (4d, J = 8 Hz, H-11, H-12, H-13, H-14), 4.10-2.95 (32H); 13C NMR (75.4 MHz, D2O/CD3OD) delta  = 145.40, 130.84, 129.38, 128.46, 126.07, 124.65, 116.65, 107.31 (aromatic C in EDANS), 137.67, 127.37, 124.65, 122.95, 120.21, 119.73, 112.89, 112.43 (aromatic C in indole), 104.17-103.72 (C-11, C-12, C-13, C-14), 61.48-61.33 (C-61, C-62, C-63).

Fluorometric Assays and Determination of the Kinetic Constants

The initial rates of the enzymatic hydrolyses of bifunctionalized substrate IX were performed at 37 °C in 0.1 M sodium acetate buffer, pH 5.0. Reactions were initiated by the addition of enzyme. Initial rate measurements were made at several substrate concentrations, which ranged from 0.1 to 4 times the value of the Km ultimately determined. Values of Km and kcat were determined using Lineweaver-Burk plots and were the result of three determinations. All kinetic studies were monitored with a Perkin-Elmer LS50 spectrofluorometer using an excitation wavelength set at 290 nm and an emission wavelength set at 490 nm.


RESULTS AND DISCUSSION

Chemoenzymatic Synthesis of the Substrate

During the hydrolysis of oligosaccharides and glycosides under thermodynamically controlled conditions, certain retaining glycosyl hydrolases such as beta -galactosidase (16), beta -glucosidase (17), and beta -xylosidase (18) display transglycosylating activity and produce mixtures of higher oligosaccharides in moderate yields and low linkage specificity. Under kinetically controlled conditions, more efficient transglycosylation reactions can be achieved when an activated carbohydrate donor is incubated with a polysaccharidase. In this case, the resulting higher oligosaccharides also exhibit good linkage specificity. This approach was first used for the high yield preparation of malto-oligosaccharides using maltosyl fluoride and alpha -amylase (19). This strategy has since been used for the preparation of natural or non-natural oligosaccharides using, for instance, amylases (9) or cellulases (20, 21).

Endoglucanase I of H. insolens was chosen for the present enzymatic synthesis because it had been shown previously to exhibit an intense transglycosylating activity using cellotetraitol as substrate, which resulted in the production of insoluble higher cello-oligosaccharides (10).

The present enzymatic synthesis (Fig. 1) was based on the transglycosylating activity of H. insolens endoglucanase I, with the following additional constraints: (i) the coupling of two distinct molecules (lactosyl fluoride II and indolethyl cellobioside V) instead of a polycondensation of a substrate on itself; (ii) the selective preparation of a beta -1,4-tetrasaccharide with minimal production of higher oligomers; and (iii) the subsequent bifunctionalization of the substrate. These constraints explain our choice of the beta -lactosyl fluoride II as the glycosyl donor in the transglycosylation reaction instead of beta -cellobiosyl fluoride, for example. The ability of cellulases to use beta -lactosyl fluoride II as a substrate has already been demonstrated (22). In fact, the galactosyl unit of lactose provides two crucial advantages. First, it prevents a higher polymerization during the condensation since oligosaccharides with axial 4-OH at the non-reducing end cannot act as acceptors in the transglycosylation reaction catalyzed by a cellulase. This enables the single addition of a single lactosyl moiety onto indolethyl beta -cellobioside V. Second, the galactosyl residue at the non-reducing end of the resulting tetrasaccharide represents a convenient site for the introduction of the second fluorescent group via the regioselective oxidation of the C-6 position by galactose oxidase and subsequent reductive amination.

The principle of the transglycosylation reaction is as follows. The enzyme initially reacts with the only substrate available, i.e. lactosyl fluoride II, with the formation of a lactosyl-enzyme intermediate and liberation of hydrogen fluoride. Then the lactosyl unit is transferred to the acceptor, indolethyl cellobioside V, yielding tetrasaccharide VI. In this scheme, the major competing reaction is the simple hydrolysis of the sugar donor and of the sugar acceptor. High substrate concentrations usually favor transglycosylation reactions. In some cases, the addition of an organic solvent to the reaction medium can help transglycosylation. In fact, early experiments involving the incubation of H. insolens endoglucanase I with beta -lactosyl fluoride II and indolethyl beta -cellobioside V in buffer only resulted in the hydrolysis of both donor and acceptor (data not shown). Various organic solvents have thus been assayed to find good conditions for the transglycosylation reaction. With the present system, we found that a 1.5:1 (v/v) mixture of acetonitrile and maleate buffer (0.05 M, pH 7.0) gave good results. Although the presence of an organic solvent appears necessary for the transglycosylation, these conditions are detrimental for the activity of the enzyme, which showed progressive denaturation after 15-20 min. The problem was circumvented by the addition of fresh enzyme during the reaction. Finally, various donor/acceptor concentrations have been explored, and the best results were obtained with donor and acceptor concentrations of 60 and 20 mM, respectively. Using the above conditions, the monofunctionalized tetrasaccharide VI was isolated with a yield of 60%. Small proportions of other oligosaccharides deriving from side reactions were also readily isolated (Table I). The bifunctionalization of tetrasaccharide VII was achieved by the oxidation of the C-6 of the terminal galactose unit by galactose oxidase followed by reductive amination. The bifluorescent tetrasaccharide IX was thus obtained with a yield of 60% from tetrasaccharide VII and an overall yield of 14% from cellobiose octaacetate. The 1H NMR spectrum of tetrasaccharide IX is shown in Fig. 2.

Table I.

Isolated yield for the various oligosaccharides produced during the enzymatic condensation


Oligosaccharide Yield

%
Glc-indolethyl 7.5
Glc-Glc-indolethyl 5
Gal-Glc-Glc-indolethyl 9.5
Gal-Glc-Glc-Glc-indolethyl (VII) 60
Gal-Glc-Glc-Glc-Glc-indolethyl 7


Fig. 2. 1H NMR spectrum of the bifunctionalized tetrasaccharide IX.
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Kinetic Assays

The efficiency of intramolecular resonance energy transfer depends on the distance between donor and acceptor and on the spectral overlap between the donor emission and the acceptor absorption (23). Among the different donor-acceptor pairs potentially useful for energy transfer measurements, the pair chosen in our study was indolethanol-EDANS, for which the efficiency of the resonance energy transfer appeared satisfactory. Indolethanol absorbs at lambda max = 290 nm and emits at lambda max = 365 nm; EDANS absorbs at lambda max = 340 nm and emits at lambda max = 490 nm (Fig. 3). In addition, these two chromophoric groups can be linked to oligosaccharides via stable bonds (9).


Fig. 3. Principle of the resonance energy transfer.
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The first important experiment was to verify the intramolecular resonance energy transfer. When the bifunctionalized tetrasaccharide IX (5-20 µM) was excited at 290 nm, the EDANS fluorescence recorded at 490 nm was five times higher than that of a solution of free EDANS at the same concentration. On the other hand, the resonance energy transfer was found to decrease the fluorescence of the indolethyl moiety at 365 nm by 50% compared with the fluorescence of the monofunctionalized tetrasaccharide VII (Fig. 4). These values, which demonstrated the resonance energy transfer, also indicated that enzymatic hydrolyses would be monitored more sensitively by the decrease of the fluorescence at 490 nm than by the increase of the fluorescence at 365 nm.


Fig. 4. UV-visible fluorescence spectra of 20 µM monofunctionalized tetrasaccharide VII (black-triangle), 20 µM bifunctionalized tetrasaccharide IX (bullet ), and 20 µM EDANS (black-diamond ).
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The substrate concentrations used must be sufficiently low to prevent intermolecular resonance energy transfer. The fluorescence intensity at 490 nm of a 20 µM solution of free EDANS was found to be almost identical to that of a solution containing EDANS and indolethyl tetrasaccharide VII at the same concentration, demonstrating that intermolecular transfer can be neglected at this concentration. The kinetic assays have therefore been performed with substrate concentrations ranging from 2 to 20 µM. Recording the fluorescence intensity of the bifunctionalized tetrasaccharide IX at different concentrations (5, 10, 15, and 20 µM) for 1 min demonstrated that the fluorescence intensity at 490 nm is proportional to the substrate concentration. The decrease in fluorescence observed during enzymatic hydrolysis (an example is given in Fig. 5) is therefore directly related to the rate of hydrolysis since for each mol of substrate which is cleaved, the total fluorescence is decreased by the intensity caused by 1 mol of EDANS. Initial rates and therefore kinetic parameters are directly available from the slope of the straight lines recorded.


Fig. 5. Decrease in the fluorescence at 490 nm during hydrolysis of the bifunctionalized tetrasaccharide IX by cellobiohydrolase I of H. insolens. The substrate (14 µM in 0.1 M sodium acetate buffer, pH 5.0) was incubated at 37 °C with 7 µg of enzyme.
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Four fungal recombinant cellulases from the fungus H. insolens have been tested for their ability to hydrolyze the bifunctionalized tetrasaccharide IX. These enzymes were two endoglucanases, EGI and EGV, and two cellobiohydrolases, CBHI and CBHII (10). The values of Km and kcat obtained for the various enzymes are presented in Table II.

Table II.

Kinetic constants in the hydrolysis of the bifunctionalized substrate IX by several cellulases from H. insolens


Enzyme Km kcat kcat/Km

µM s-1 s-1 µM-1
Endoglucanase V 0a 0a 0a
Endoglucanase I 8 27 3.4
Cellobiohydrolase I 33 0.40 0.012
Cellobiohydrolase II 6 0.023 0.004

a  Not hydrolyzed in the conditions of the assay.

EGV is the only enzyme with which no hydrolysis was detected. This result is compatible with earlier observations that EGV contains at least six subsites and that the catalytic constants for the hydrolysis of cellotetraitol are very poor with a Km above 1,000 µM and a kcat = 0.84 s-1 (10). On the other hand, hydrolysis of cellohexaitol by EGV was much more efficient (Km = 52 µM and kcat = 14 s-1) (10). The bifunctionalized tetrasaccharide IX is probably too short, and/or the chromophoric groups perhaps prevent the productive binding of the substrate to the enzyme.

The second enzyme tested was EGI, the enzyme used for the enzymatic synthesis of the substrate. EGI proved to be very efficient for the hydrolysis of the bifluorescent substrate IX with values of kcat (27 s-1) and kcat/Km (3.4 s-1 µM-1) comparable to the values of 40 s-1 and 2.9 s-1 µM-1), respectively, obtained with the same enzyme using cellopentaitol as substrate (10). This observation shows that the large fluorogenic groups introduced on the tetrasaccharide have little influence on the hydrolysis of the substrate by this enzyme.

Surprisingly, the two cellobiohydrolases, CBHI and CBHII core, were also able to hydrolyze the bifunctionalized substrate with Km values in the micromolar range (Table II). The kinetic parameters show, however, that these two enzymes are less efficient than EGI since their catalytic constants were found to be, respectively, 0.40 and 0.023 s-1 (Table II). The value of 0.40 s-1 obtained with CBHI, albeit low, is comparable to the value of 0.96 s-1 obtained during the hydrolysis of cellopentaitol (10). This result indicates that the two fluorogenic groups of the substrate do not affect very significantly hydrolysis of the substrate by CBHI. CBHII core is also able to cleave the bifunctionalized tetrasaccharide, although with a catalytic constant largely reduced compared with that observed against cellopentaitol (0.67 s-1) (10). The sites of cleavage of the bifunctionalized substrate by EGI, CBHI, and CBHII were analyzed by thin layer chromatography (data not shown). EGI and CBHI were found to be able to hydrolyze the substrate at two points, whereas CBHII could cleave only one of the interosidic bonds (Fig. 6).


Fig. 6. Cleavage sites of the bifunctionalized tetrasaccharide IX by the various cellulases used in this work as determined by thin layer chromatography.
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CBHI and CBHII from H. insolens display high sequence similarity with CBHI and CBHII from Trichoderma reesei (63 and 58% sequence identity, respectively), whose three-dimensional structures have been determined (24, 25). The only feature common to these otherwise dissimilar protein structures is the topology of their active sites. In both cases, long loops cover part of the active site cleft, and the resulting tunnel enables the threading of a cellulose chain (25). The tunnel-shaped active site of cellobiohydrolases permits the liberation of the cellobiose product while maintaining the cellulose chain bound to the enzyme. This active site topology allows the processive, recurrent hydrolysis of cellulose chains into cellobiose (26). An important question remains with the site of the initial attack of cellulose. Three possibilities exist: (i) entry of the substrate chain end from only one entrance of the tunnel resulting in a selectivity for a single chain end type; (ii) entry of reducing chain ends from one side of the tunnel while non-reducing chain ends could enter from the other side; and (iii) a sporadic opening of the loops to allow binding of a cellulose chain in the active site. Current models favor the first possibility with a selective chain end attack for cellobiohydrolases, with CBHI starting from the reducing ends (27, 28) and CBHII starting from the non-reducing ends of cellulose chains (28, 29). The fact that the two recombinant cellobiohydrolases we have assayed are able to degrade the bifunctionalized substrate carrying non-carbohydrate substituents at both ends argues against the specific chain end recognition by cellobiohydrolases and suggests that a different model for the initial attack should be envisioned.

In conclusion, the use of the transglycosylating activity of the recombinant endoglucanase EGI from H. insolens has provided a rapid and efficient synthesis of a bifunctionalized tetrasaccharide from two modified disaccharides. This chemoenzymatic approach has led to the preparation of a useful substrate for the biochemical characterization of cellulases since it provides a very sensitive assay that can be monitored continuously. Furthermore, the comparison of catalytic constants with those obtained on reduced cellodextrins shows that the fluorophores do not seem to influence the enzymatic hydrolysis by cellulases having a low number (<= 5) of subsites. For cellulases such as H. insolens EGV which have a large number of subsites (>5), the synthesis of a longer oligosaccharide should be envisaged. Since the efficiency of the resonance energy transfer depends both on the distance between the two chromophores and on the spectral overlap of donor and acceptor, the use of another donor-acceptor pair that would show a better spectral overlap should be considered, to compensate for the increased distance between the two fluorophores when one or two extra glucosyl residues are added. In addition to providing a sensitive assay for endoglucanases, the bifunctionalized tetrasaccharide was also found to be hydrolyzed by two cellobiohydrolases, suggesting that these enzymes do not specifically require a free chain end for their action. Work is currently under way in our laboratory to test this hypothesis further.


FOOTNOTES

*   This work was funded by Research Grant BIO2 CT 94 3018 from the European Community. 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.
   CERMAV-CNRS is affiliated with the Joseph Fourier University, Grenoble.
par    To whom correspondence should be addressed: CERMAV-CNRS, BP 53, F-38041 Grenoble cedex 9, France. Tel.: 33-4-7603-7603; Fax: 33-4-7654-7203.
1    The abbreviations used are: CBH, cellobiohydrolase(s); EDANS, 5-(2-aminoethylamino)-1-naphthalenesulfonate; EG, endoglucanase; FAB-MS, fast-atom bombardment mass spectrometry; HPLC, high performance liquid chromatography.

Acknowledgments

We are grateful to Drs. S. Cottaz (CERMAV) and G. Davies (University of York) for useful discussions. We also thank C. Gey (CERMAV) for performing the NMR and Dr. C. Bosso (CERMAV) for performing the FAB-MS.


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